DEPARTMENT OF THE INTERIOR ITED STATES GEOLOGICAL SUKVEY GEORGE OTIS SMITH, Director Water-supply Paper 339 QUALITY OF THE SURFACE WATERS OF WASHINGTON BY WALTON VAN WINKLE Prepared in cooperation wiih the State Board of Health of "Waahington WASHINGTON GOVERNMENT PEINTINQ OPFIOB 1914 > ^ DEPARTMENT OF THE INTERIOR UNITED STATES GEOLOGICAL SURVEY GEORGE OTIS SMITH, Director Water- StjppIjY Paper 339 t QUALITY OF THE SURFACE WATERS OF WASHINGTON ^^^, BY WALTON VAN WINKLE Prepared in cooperation with the State Board of Health of "Washington WASHINGTON GOVERNMENT PRINTING OFFICE 1914 d: of 0, JUL 30 ill Oy^ ^ V. CONTENTS. Page. Outline of investigation 7 Acknowledgments 8 Natural features of Washington 9 Location and extent 9 Topography 9 Drainage 10 Rivers 10 Lakes 12 Creology 12 Rocks 12 Soils 13 Climate 13 Economic features 15 Population 15 Agriculture ,15 Manufactures and commercial industries 16 Natural waters 17 Constituents 17 Uses of water 18 Varieties of use. . : 18 Domestic use 18 Boiler water 19 Corrosion 19 Formation of scale 20 Foaming 21 Factory waters 22 Chief industries affected 22 Breweries 22 Paper mills 23 Wool scouring, bleaching, and dyeing works 24 Laundries 24 Other industries 25 Purification of water 25 Filtration 25 Types of filters 25 Slow sand filtration 25 Rapid sand filtration 26 Sterilization 28 Softening 29 Methods of analysis 31 Interpretation of the results of analysis 31 Industrial interpretation 31 Geochemical interpretation 33 Skagit River 35 General features of drainage basin 35 Character of the water 36 3 4 CONTENTS. Page. Wood Creek 39 General features of drainage basin 39 Character of the water 39 Cedar Eiver 40 General features of drainage basin 40 Character of the water 42 Green Kiver 45 General features of drainage basin 45 Character of the water 45 Chehalis River 46 General features of drainage basin 46 Chehalis Hiver at Centralia 47 Character of the water 47 Wynoochee Hiver 51 General features of drainage basin 51 Character of the water. 52 Columbia Hiver basin. 52 General features 52 Spokane Biver 54 General features of drainage basin 54 Character of the water 55 Okanogan Hiver 57 General features of drainage basin 57 Character of the water 58 Wenatchee Biver 60 General features of drainage basin 60 Character of the water 60 Yakima Biver 63 General features of drainage basin 63 Naches Biver 64 General features of drainage basin 64 Character of the water 64 Yakima Biver at Clealum 66 General features 66 Character of the water 66 Yakima Biver at Prosser 69 General features 69 Character of the water 69 Snake Biver 72 General features of drainage basin 72 Character of the water 73 Klickitat Biver 77 General features of drainage basin 77 Character of the water 78 Columbia Biver at Northport , 80 General features 80 Character of the water 80 Columbia Biver at Pasco 83 General features 83 Character of the water 84 Columbia Biver at Cascade Locks 86 General features 86 Character of the water 87 CONTENTS. 5 Page. Average chemical composition of river water 93 Economic value of the*rivera 96 Denudation 98 Influence of natural features 100 Precipitation 100 Wind-borne material 100 Forestation 101 Character of the rocks 101 Conclusion 102 Index - 103 ILLUSTRATIONS. Page. Plate I. Map of Washington showing principal natural features 7 II. Map of Washington showing drainage and location of sampling sta- tions 8 Figure 1. Diagram showing relative amounts of dissolved and suspended mate- rial carried by rivers of Washington 94 U.S. GEOLOGICAL SURVEY GEORGE OTIS SMITH , DIRECTOR PAPER 339 PLATE 1 125 124' il7^ A-B.;?JSHA.< •:0.-:V«.V'ASH.i MAP OW M QUALITY OF THE SURFACE WATERS OF WASHINGTON. By Walton Van Winkle. OUTIilNE OF INVESTIGATION. The value of water for any particular use is determined by the nature and amount of the material it holds in suspension and solution — that is, its quahty. Water for drinking must be free from poisonous chemicals or disease-producing organisms and from excessive amounts of dissolved materials ; preferably it should be clear, odorless, color- less, and palatable. Water for cleansing should be soft and should be free from large amounts of iron in order not to cause waste of soap or spots and stains on clothing. Water for steam generation should not contain materials that form excessive deposits of scale or that corrode the boilers. Water for industrial processes should not con- tain substances which will combine with the raw material or with the 'bleaches or dyes to the injiu'y of the finished product or the waste of materials of manufacture. Analyses of ''spot samples" of water are often misleading, espe- cially of samples collected in regions of sHght rainfall or marked seasonal variations in precipitation. The data obtained by study of many samples systematically collected over long periods, however, are not only locally important, affording essential information to municipaUties and manufacturers, but they are also scientifically valuable, as they illuminate many problems of physiography, chemi- cal denudation, and geochemistry. Late in 1909 the United States Geological Survey and the State Board of Health of Washington began a cooperative study of the qual- ity of the surface waters of the State of Washington, including their seasonal variation in composition and in physical characteristics, and the pollution to which they are subject. No systematic study of the quahty of the surface waters of Wash- ington had previously been made, though miscellaneous analyses of water from a few lakes and rivers have been published in periodi- cals or in special reports to municipalities, and analyses of serial samples of water from Salmon and Palouse rivers were made by the United States Reclamation Service in 1905.^ 1 stabler, Herman, Some stream waters of the western United States: U. S. Geol. Survey Water-Supply Paper 274, pp. 80, 111, 1911. 7 WATEFi-SUFPLY PAPER 339 PLATE I MAP OF WASHINGTON SHOWING PRINCIPAL NATURAL FEATURES Scale 2,500.000 25 50 75 lOOlNIiles 8 QUALITY OF SURFACE WATEBS OF WASHINGTON. The bacteriologic work of the investigation was done by the State Board of Health, the chemical work by the United States Geological Survey, and the field expenses were shared by both organizations. The writer was detailed to perform the chemical and field work under the direction of R. B. Dole, chemist of the water-resources branch of the Geological Survey. The chemical determinations were made at the city hall at Seattle in a room procured through the courtesy of Mr. Thompson, the city engineer, until March, 1910, when, in response to an invitation from the University of Washington, the laboratory was moved into quar- ters in the chemistry building of that university. In the chemical work the writer was assisted during the greater part of the time by Mr. McClintock Taylor. Sampling stations were estabHshed at certain points, from which daily samples of water were forwarded to the laboratory during the periods indicated by the dates. Each of the stations, except that at Okanogan and that near Montesano, was inspected from time to time by the writer. The stations are listed below and their locations are shown on Plate II. Instructions in collecting and plating bacteriologic samples were given the collectors at aU places except Okanogan, but the results of the bacteriologic investigations, which were conducted by Dr. E. P. Pick, bacteriologist of the State Board of Health, have not been included in this report. Sampling stations on streams in Washington. Stream. Sampling point. Collections. Begun. Discontinued Cedar River , Chehalis River Columbia River. . Do Do Green River Klickitat River... Naehes River Okanogan River., Skagit River Snake River Spokane River Wenatchee River. Wood Creek Wynoochee River, Yakima River Do Gaging station at Seattle intake near Ravensdale. Bridge above Centralia Ferry, Northiwrt Waterworks intake, Pasco Above rapids at Cascade Locks Bridge near hotel, Hot Springs Gaging station near railroad station, Klickitat . Power house near Naches Near Okanogan North Pacific Ry. bridge near Sedro Woolley. North Pacific Ry. bridge near Burbank Bridge above Spokane Bend between gaging station and Cashmere. . Inlet into city reservoir, Everett Fry's camp, 20 miles above Montesano 100 yards below wagon bridge at Clealum. . . . . Flouring mill above Prosser Feb. 1, 1910 ....do Jan. 22,1910 2. 1910 2, 1910 13, 1910 1, 1910 1, 1910 ....do ....do Mar. 31,1910 Feb. 1, 1911 Mar. 13,1910 Feb. 1, 1910 do /Feb. \May rMar. \Aug. Feb. Mar. 13,1910 July 17,1910 Feb. 1, 1910 Aug. 20,1910 Jan. 31,1911 Do. Do. Apr. 21,1910 Jan. 31,1911 Dec. 31,1910 Aug. 14,1912 Aug. 18,1910 Jan. 31,1911 June 30,1910 Jan. 16,1911 Jan. 31,1911 Do. Do. Do. Do. Aug. 19,1910 Jam 31,19U Do. ACKNOWLEDGMENTS. Thanks are due especially to the officials of the University of Wash- ington, particularly to Dr. Thomas H. Kane, president of the univer- sity, and to Dr. H, G. Byers, director of the chemical laboratories, for >r , W. T (lTIONS ajn 60 70 Mile =3 U.S. GEOLOGICAL SURVEY OEORGE OTIS SMITH, DIRECTOR WATER-SUPPLY PAPER 339 PLATE I <''"0m U.S. Land Office map ■^IF OF WASHINGTON SHOWING SAMPLING STATIONS AND DRAINAGE BASH Boundary of drainage basins •Sampling station Scale 1.500,000 nn Miles 10 10 20 30 40 5Q ^ d NATUEAL FEATURES OF WASHINGTON. 9 furnishing laboratory space, fuel, light, and water; and to Mr. Thomp, son, city engineer of Seattle, and to the engineer in charge of tests- Mr. C. Moore. The hearty cooperation of Dr. A. P. Duryee, of Ever- ett; Mr. A. B. Youngs, of Seattle; Dr. B. M. Grieve, of Spokane; and Mr. Charles Ewarts, of Aberdeen, rendered possible the collection of samples from Wood Creek, Cedar River, Spokane River, and Wynoochee River. The serial samples at Okanogan were collected by an employee of the United States Reclamation Service, through the kindness of Christian Anderson, project engineer. The writer has drawn freely on the geologic reports of the Washing- ton Geological Survey and the United States Geological Survey for information regarding the geology of the State, and on the publica- tions of the United States Weather Bureau for information regarding climate and precipitation. He wishes to extend special thanks to Air. Henry Landes, State geologist, for valuable personal assistance in matters pertaining to local geology, and to Messrs. J. C. Stevens and F. F. Henshaw, of the district office of the United States Geological Survey in Portland, Greg., for assistance in obtaining records of stream discharge. NATURAL FEATURES OF "WASHINGTON. LOCATION AND EXTENT. The State of Washington, occupying the extreme northwest corner of the continental United States, exclusive of Alaska, extends from latitude 46° to 49° north (see PI. I) and longitude 40° to 47° 30' west from Washington meridian and comprises an area of 69,127 square miles, of which 2,291 square miles is water.^ Its land surface is therefore greater than the combined areas of the New England States and nearly as great as that of the New England States and New Jersey or of Missouri. The water surface includes much of Puget Sound and a nimaber of small lakes. TOPOGRAPHY. The most prominent feature of relief in Washington is the Cascade Range, which crosses the State from north to south and divides it into two regions of dissimilar climate — to the west a region of abundant rainfall, cool summers, and mild winters, and to the east a region of moderate or scanty rainfall, hot summers, and cold though not severe winters. Viewed from a point below the 6,000-foot level, the Cascade Range appears to form a series of jagged peaks, but a view from a simamit reveals the fact that all the peaks are remnants of a long plateau, perhaps 50 miles wide, and that the valleys have resulted from stream and glacial erosion. Probably eveiy observer » Gannett, Henry, The areas of the United States, the States, and the Territories: U. S. Qeol. Survey BuU. 302, p. 8, 1906. 10 QUALITY OF SURFACE WATERS OF WASHINGTON, who has crossed these mountains has noticed this fact and many have recorded it in their published descriptions. Most of the mountain tops are 5,500 to 6,000 feet above sea level, although isolated peaks rise to much greater heights. Mount Rainier, the highest .in the State (altitude 14,364 feet), is not one of the peaks of the Cascades but is an extinct volcano resting on the western slope of the range. Mount Baker, Mount St. Helens, and Mount Adams are also flanking volcanic peaks and are not integral parts of the range. West of the Cascade Range and at its base is a long troughlike valley the northern part of which is submerged and forms Puget Sound. This valley is separated from the coastal plain on the south- west by a low divide called the Coast Range, which is one of the minor topographic features of the State. The Olympic Mountains, their peaks capped by perpetual snow, rise abruptly from the western edge of Puget Soiuid. These moun- tains, hke those of the Cascade Range, are remnants of a high plateau, now deeply dissected and eroded ; and, Hke the Cascades, they reveal their original form only from their summits. Their average eleva- tion above sea level is more than 6,500 feet, but individual peaks attain altitudes of 9,000 feet and more. Their slopes are steep and in many places precipitous, and the short, steep valleys leading from their uplands contain torrential streams of considerable size. The eastern slopes of the Cascade Mountains merge at their base into the Columbia River plains, which occupy the eastern part of the State. These plains appear practically level to the casual observer, but in reahty they rise gently eastward and southeastward untU they merge into the foothills of the Blue Mountains of Oregon. The east- ern and southern parts of the plaius are rolling prairie land and con- stitute the wheat belt of Washington. The plains are cut in all directions by canyons of living or ancient streams. Snake River traverses the whole width of the plains in Washington in a canyon whose walls are in most places nearly perpendicular cliffs and whose average depth is 2,000 feet. Between upper Columbia River and the Cascade Range are the Okanogan highlands. DRAINAGE. RIVERS. The drainage of the State passes to the Pacific through Columbia River, streams tributary to Puget Sound, and minor coastal streams. Columbia River, the principal river of Washington, receives the drainage of the entire State east of the Cascade Range and of a narrow strip in the southwestern part. The area of its basin in Washington comprises 48,000 square miles, or 18.5 per cent of the total area drained by the river, the rest of which is in Oregon, Idaho, ISTATURAL FEATURES OF WASHINGTON. 11 Montana, and Canada. It includes Avithin its boundaries all varie- ties of topography. The rugged, eroded slopes of the Cascades border it on the west; the lower ranges of the Okanogan highlands, with their deeply gouged glacial troughs, form its northern border; the rolling prairies of the eastern Washington '^Palouse country" and the level Columbia plains comprise its eastern portion; and the short, narrow valleys of the Khckitat region and the gently sloping, mature valleys of the CowUtz and Kalama region characterize its southern portion. The territory between Cascade Mountains and Columbia River contains wide, fertile, mountain-girt valleys that form the chief apple-growing section of the State. The cHmate of the basin is as diversified as its topography. The plains are hot in summer, but not very cold in winter; but the roUing uplands skirt- ing them are subjected to both hot summers and cold winters. The valleys bordering the Cascades are characterized by warm summers and cold winters and on the higher elevations of the Cascades the climate is extremely rigorous. Rainfall is copious in the summit region of the Cascades, but decreases eastward until it amounts to only 5 or 6 inches a year in the lower portions of the Columbia plains. It is greater in the eastern section and in the Okanogan highlands and Blue Mountain region, but is still inadequate for full agricultural development. Much of the drainage area is treeless and forests are confined to the mountainous portions. The principal tributaries of the Columbia River in Washington are Snake River, the largest, and ColviUe, Spokane, Okanogan, Methow, Chelan, Wenatchee, Yakima, Khckitat, Lewis, Kalama, and Cowhtz rivers. Most of the rivers rising on the western slopes of the Cascades flow into Puget Sound. Many of these are short and relatively unimportant, but some, such as Skagit River, are of considerable magnitude. The streams draining the eastern and northern slopes of the Olympic Mountains also flow into Puget Sound. These are aU short and swift and afford many power sites. Precipitation is abundant throughout the area draining to Puget Sound except along the northern shore of the sound itself, which receives an exceedingly low rainfall. The cUmate is moderate, the summers being cool and the winters mild. Sunshine is not abundant; the sky in summer is often obscured by haze or by smoke from forest fires and in winter is overcast by clouds. Forests cover most of the uplands of the basin. The minor coastal streams drain a narrow strip of country extend- ing from the Straits of Juan de Fuca to the mouth of the Columbia. The only large stream in this area is Chehalis River. Other rivers of the region are the Soleduck, Hoh, Queets, and Queniult, draining the western slopes of the Olympic Mountains, and Willapa River, draining the Coast Range. Rainfall in this strip is copious and the climate is mild. Much of the area is forested. 12 QUALITY OF SURFACE WATERS OF WASHINGTON. Two periods of high water are usual, one in spring or early summer and the other in late autumn or early winter. The floods in spring usually last longer, but those in winter are commonly more violent. When rain and melting snow are concomitant, freshets are sure to be severe. A southerly chinook wind on the Cascades, especially if it is accompanied by a rainstorm and follows a period of heavy snowfall, causes destructive floods that at times have paralyzed traflS.c across the Cascade Mountains for days. The landslides that sometimes accompany sudden thaws on the slopes of the Cascades have caused great loss of life and property. LAKES. Lake Chelan occupies a glacial trough 48 miles long and about 1 mile wide, extending southeastward from the Cascade Range in the northern part of the State. Its water surface is 1,080 feet above sea level. This lake is perhaps one of the most picturesque in America. Other lakes, mostly small, lie in the Okanogan highlands. The water of many of them is brackish, and that of some, according to available information, contains large amounts of sodium sulphate. The beds of the coulees in the Big Bend region contain several small and a few large lakes. Many of these '4akes^' are really playas or intermittent shallow pools; some are fresh and fill widenings of the channels of the small streams flowing through the coulees ; others are alkaline sinks or residual lakes with no outlet. Moses, Alkali, and Freshwater lakes in Grand Coulee, and Tule, Sylvan, Pacific, and Crab lakes in Crab Creek coulee are the best known. All contain carbonate water. Rock Lake and Colville Lake are situated in the eastern part of the State. The Olympic Mountains contain two principal lakes, Queniult and Crescent. The latter is growing in popularity as a summer resort for residents of the cities around Puget Sound. Silver Lake, in Cowlitz Basin, is the only important lake in the southern part of the State. The region of glacial drift around Puget Sound contains many fresh-water lakes. Lake Washington and Lake Union, the former bordering and the latter within the city of Seattle, may be mentioned. GEOLOGY. ROCKS. The geology of Washington in general has been studied by several writers, and selected areas have been investigated in considerable detail. The following statements have been drawn from the pub- lished writings of many authors, to whom credit is hereby given: Paleozoic gneisses and schists with some limestones and granites are abundant in the Okanogan highlands and give place southward to the basalt of Miocene age. The formations of the Olympic Moun- STATURAL FEATURES OF WASHINGTON. 13 tains include met amorphic rocks of Jurassic age encircled by Upper Cretaceous sediments that along the coast are covered by late Ter- tiary sediments. The core of the mountain mass is granitic. The Cascade Kange is a buge uplifted mass of great length and width. The core, at least in the northern portion, is composed of granites and granodiorites, in large areas flanked by Paleozoic and later metamorphic rocks — schists, gneisses, and serpentines. In the middle section of the range andesitic and basaltic formations are fomid in contact with the Mocene basalt of Columbia River and with various Tertiary sediments and metamorphic rocks. The rocks of the southern section are largely basaltic. The plains of Columbia and Snake rivers and the Blue Mountain uplift are covered with the Mocene basalt, overlain in part by the later Miocene sediments of the Ellensburg formation. The Puget Soimd trough is filled to a depth of several hundred feet with Quaternary glacial deposits, but in the eastern borders Eocene and Mocene sedimentary formations are exposed. SOILS. The soils of eastern Washington are eoUan, or wind borne, and residual, derived by decay from underlying rocks. They are ex- tremely fertile and produce excellent crops imder cultivation. Ac- cording to Calkins * the eohan soils, which predominate and are very thick, are light colored, very friable silty loams of fine, open texture. The residual soils from basalt are darker, and in many places angular pieces of basalt are mingled with the fine loam. The soils of the intermountain valleys are sands, sandy loams, or clays in the southern and central sections and stony, gravelly, or sandy soUs in the northern, glaciated sections. The soils of the western region are largely glacial detritus — gravels or sandy loams. The southern part of the coastal region is overlain by silty clay loams and silty loams derived from the Tertiary sand- stones and shales. Many of the glacial soils are poor in nitrogen, and their enrichment through the growth of leguminous plants greatly aids production of crops. The deficiency of plant food and organic matter is due both to the origin of the soils and to the exces- sive leaching they have undergone. CLIMATE .2 Qf the two unequal areas into which the Cascade Range divides the State, the western is a region of abundant rainfall, cool summers, and mild winters, and is for the most part covered by forests of 1 Calkins, F. C, Geology and water resources of a portion of east-central Washington: U. S. Geol. Survey Water-supply Paper 118, p. 45, 1905. 2 Abstracted from Climatology of the United States, by A. J. Henry: U. S. Weather Bur. Bull. Q, p. 926, 1906. 14 QUALITY OF SURFACE WATERS OF WASHINGTON. gigantic evergreens; the eastern is a region of moderate or scanty rainfall, hot summers, and cold but not severe winters, and the greater part of it is treeless. To say that the normal annual temperature of the State is 49.3° F. and the normal annual precipitation 37.1 inches is to give informa- tion that, though correctly deduced, is almost wholly valueless for any particular locahty. Only one broad generahzation can safely be made: The area west of the Cascade Eange is wet and that east of it is dry. Greater accuracy requires the subdivision of the wet sec- tion into a moist and a very wet area, and the dry section into semi- arid and arid. The wet section Hes between the ocean and the sum- mits of the Coast Range and Olympic Mountains. Its annual rain- fall is 60 to 120 inches, and 75 per cent of this occurs during the so-caUed ^'wet season,'^ from November to April. In the semiarid area, comprising the eastern and northern portions of the State, the annual precipitation as rain and snow is 12 to 25 inches. The very dry or arid area, in the central portion of the State east of the Cascades, receives annually less than 12 inches of rain and snow. The climate of the coastal strip is almost marine, except occasion- ally when winds blow from inland at the time cold waves of great intensity are overspreading Alberta, British Columbia, and Montana. The mean annual temperature is 47° to 51°. The normal tempera- ture in January is 36° to 42°, in April 46° to 49°, in July 57° to 63°, and in October 48° to 55°. The temperature has never been lower than 10° above zero at Aberdeen. It almost never exceeds 90°, and is below freezing only about 40 times a year. The cHmate in the Puget Soimd basin is somewhat similar to that of the coastal strip in mean annual and monthly range of tempera- ture, but it is greatly modified by cold and warm winds coming across the Cascade Mountains. The rainstorms that are so frequent in winter have about the temperature of the sea in this latitude, and hence the rainy days in winter are very mild. During dry spells in winter the air is sharp and frosty, as it either is coming from the region east of the Cascade Mountains or is a descensional current from an anticyclonic area which is central over Puget Sound. The extremes of temperature recorded for the region are 102° (at Centralia) and 6° btlow zero (at Blaine). The climate east of the Cascades is essentially continental, although it is undoubtedly modified by storms and by air currents from the sea. There is a great diversity and range of temperature as well as rainfall. Stevens and Douglas counties, the former in extreme northeastern and the latter in central Washington, are the coldest. The annual average temperature in Stevens County is 44° to 46°, ranging from 20° in January to 68° in July. In the country around Spokane the temperature ranges from about 24° in January to 68° ECONOMIC FEATURES. 15 in July. At Spokane 30° below zero and 104° above zero have been recorded. Winters in tbe settled part of Kittitas County are cold but not severe except for an occasional cold snap lasting a few days. The summers are short and sometimes hot. In all the southeast counties the simamers are hot and the winters are mild, with Uttle snowfall except in the mountains and only short periods of moder- ately cold weather. In the region about Lake Chelan and in the vaUey of Okanogan River the winters are phenomenally mild. The dominant wind for the year over the Puget Sound basin is southerly; along the coast it is south to west; these are the rain- producing winds. The northerly and easterly winds are, for the most part, dry. In summer the winds are very moderate. The prevailing winds east of the Cascades are from the southwest, though local topography in Wenatchee and Yakima valleys make the direction northwest. Occasionally during summer hot desiccating winds, inju- rious to crops, blow from the north and east over the plains of the eastern division. Hailstorms sometimes occur, but they are almost invariably light and do little damage except to fruit. ^^ Dust storms," so-called, occasionally occur in the Walla Walla, Snake Eiver, and Yakima valleys, but they are more disagreeable than injurious. ECONOMIC FEATURES. POPULATION. The United States census of 1910 gave the population of Wash- ington as 1,141,990, the increase since 1900 having been 120.4 per cent. That more than half the inhabitants now dwell in only 27 cities indicates the wonderful industrial and commercial growth of the State in recent years. More than one-fifth of the people reside in two counties bordering on Puget Sound and comprising only 5.7 per cent of the total area of the State. Increase in rural population has been marked and well distributed. Spokane, Walla Walla, and North Yakima, three of the seven largest cities of the State, are pri- marily agricultural centers, and the density of rural population in the counties in which they lie is from 5.5 to 18.1 persons per square mile of land. Future development wiU probably result in a generally increased rural population, but in a much more largely increased urban population, for manufacturing and commerce will undoubtedly lead agriculture. AGRICXrLTTIRE.i Washington is divided by differences in rainfall, temperature, and soils into three great agricultural provinces. The western part of the State, from the Cascade Range to the ocean, produces vegetables I All figures from the Thirteeath Census of the United States, 1910. 33476°— wsp 339—14 2 16 QUALITY OF SURFACE WATEES OF WASHINGTON. and other crops that require much moisture. The intermountain country, the valleys of the Okanogan highlands, and the uplands of the Spokane country form the apple belt, in which prunes, cherries, and other fruits also are raised. The Columbia plains and the foot- hills of the Blue Mountains are the wheat and cattle regions. Lin- coln, Whitman, Adams, Walla Walla, Douglas, Grant, Franklin, and Spokane counties produce seven-eighths of the entire wheat crop, which in 1911 was 50,000,000 bushels. Stevens, Spokane, and Whit- man counties produce one-fifth of all the hay and forage. Barley is grown principally in Columbia, Garfield, Walla Walla, Whitman, and Lincoln counties. Spokane County produces the most potatoes, but each county produces good crops of this vegetable. Corn growing is confined to the counties east of the Cascades, and hop raising is practiced almost exclusively in Yakima County. Yakima and We- natchee valleys and the extreme eastern part of the State produce most of the orchard fruits. Much of the orchard and farm land must be irrigated; indeed, irrigation is practiced on 13.6 per cent of all the farms in the State, and the acreage is rapidly being increased. The United States Keclamation Service has placed under irrigation 55,690 acres, the Indian Service 35,000 acres, and corporate, cooperative, or indi- vidual enterprises 243,688 acres. Several large irrigation projects are in course of construction and others are contemplated, so that large additions to these acreages will soon be made. MANUTACTUBES AND COMMERCIAL INDUSTRIE S.i Washington is the chief lumber-producing State in the Union, and making or handling wood or its products constitutes nearly half of the conmiercial activity of the State. The total amount sawed in 1910 was 4,097,492 thousand feet board measure.^ This lumber was used rough, dressed, or as boards, posts, cordwood, and shingles. The amount of standing timber is, however, at the present time less than in Oregon, whose production is only slightly more than half that of Washington. The standing timber in Washington is chiefly in private ownership, as is shown by the following table: Ownership of standing timber in Washington. [Billion feet board measure.] Private 294. 6 National forests 81. 6 AU other -.. 14.8 Flour and grist milling, slaughtering and meat packing, canning and preserving, and printing and publishing are other leading indus- 1 All figures from Thirteenth Census of the United States, 1910, unless otherwise noted. ' Statistical abstract of the United States, Dept. Commerce and Labor, Bureau of Statistics, p. 167, 1911. NATURAL WATERS. 17 tries. Minor industries of the State include the production of malt liquors, leather goods, food preparations, and ice. The fisheries employ nearly 5,000 men, 190 vessels, and 2,800 small boats. Salmon and oysters are the chief products. The lumber industry, by its sawdust waste and the soda refuse of its pulp mills; the leather industry, through its waste liquors; and the wool industry, through its scouring and dye liquors, affect the quality of the stream waters and thereby alter their economic value for municipal and industrial use. Proper protective legislation should regulate the disposal of the wastes of these industries. NATURAL WATERS. CONSTITUENTS. Even rain, the purest natural water, contains appreciable amounts of organic and inorganic material, both in solution and in suspension. Rain falling near the seacoast contains more or less dissolved salt that is drawn up from the ocean with the water vapor — a fact that has been utiHzed in the study of pollution of surface waters near coasts by determining the quantity of chlorine carried by normal unpolluted waters.^ Charts indicating the amount of chlorine brought down in rain can then be prepared by plotting the results of such determina- tions and connecting points at which equal amounts are found, thus establishing lines of equal chlorine (isochlors). Abnormalities resulting from human pollution can be discovered by comparing analyses of other surface waters with these charts. But isochlors are useful only near the coast in humid regions not containing chloride-bearing rocks, and they are of doubtful value in regions of great seasonal variation of rainfall. Streams flowing through arid regions contain relatively large amounts of chlorides left after incomplete leaching of the sedimentary rocks, and though the amount of native chlorine may be sUght where the rocks are mostly volcanic or plu tonic unpolluted waters may be high in chlorine because of concentration of ^'cycHc'^ or wind-borne chlorine by evaporation. Carbon dioxide and oxygen, the important gases dissolved in rain- water, are powerful agents of solution and oxidation, and the water containing them, having reached the earth, begins at once to acquire a further charge of dissolved matter. The carbon dioxide already present is augmented by that produced by the decay of vegetable matter on the surface of the ground or in the soil. Silica and the rock silicates are practically insoluble in pure water, but hydrated silicates are easily decomposed in weak solutions of carbonic acid, and > Jackson, D. D., The normal distribution of chlorine in the natural waters of New York and New Eng- land: U. S. Geol. Survey Water-Supply Paper 144, 1905. 18 QUALITY OF SURFACE WATERS OF WASHINGTON. '' quartz is attacked and dissolved by prolonged digestion in even dilute alkaline carbonate solutions. "* Silicate rocks are thus broken down by the action of water bearing carbon dioxide, and silica and alkalies are dissolved. The dissolved carbonic acid also attacks any hmestone with which it comes into contact, for although calcium carbonate is only shghtly soluble in pure water it goes readily into solution in the presence of carbonic acid, probably as calcium bicar- bonate. Direct solution, hydrolysis, and double decomposition all aid in bringing other materials into solution. Many secondary rocks, such as gypsum, enter directly into solution, and limestone may be dissolved by interaction Avith alkali sulphates. All elements are soluble in water to some extent, but relatively few are found in appreciable amounts in natural waters. The im- portant materials usually found are siHca, iron, alumina, calcium, magnesium, sodium, potassium, carbonates, bicarbonates, sulphates, chlorides, nitrates, and organic matter. USES OF WATER. VARIETIES OF USE. Water is of general and diversified use in the industries. It is used directly to furnish power, to transport heat or materials, or to perform an essential part in some processes of production, and indirectly to produce power through steam or electricity. Some idea of the magnitude of the indirect use, which during recent years has been the greater, may be gained by considering that a stationary boiler requires approximately 10 pounds of water an hour to furnish 1 horsepower to a triple-expansion condensing engine, and a boiler for a noncondensing engine, such as a locomotive, requires almost twice that amount. Few engines, however, are operated with so little water; the more modern and larger condensing engines waste an insignificant amount, but the older and smaller engines use many times the amount theoretically necessary. DOMESTIC USE. Drinking water must be free from suspended or dissolved matter which may endanger health or which may render it unpalatable. Even a small amount of iron gives a disagreeable taste to water and injures the quality of tea and coffee by combining with the steep hquors of the beverages to produce inks. The presence of sodium chloride in water in amounts greater than 400 parts per million can be detected by taste by most persons, and water containing more than ' Lunge and Millberg, Zeitschr. angew. Chemie, 1897, pp. 390, 425. Cited by Chase Palmer in The geochemical interpretation of water analyses: U. S. Geol. Survey Bull. 479, p. 23, 1911. I^ATUEAL WATEES. 19 1,000 parts per million would be palatable to few. The use of water containing large amounts of sulphates tends to produce unpleasant laxative effects. The esthetic quality of water used for drinking is also important, and for this reason it should be clear, colorless, and odorless. Suspended matter not only renders water esthetically unattractive but clogs pipes and valves, reduces the capacity of reservoirs, stains clothes, and produces sludge in boilers. For domes- tic uses other than cooking and drinking water should be soft, as hard water increases the consumption of soap by forming insoluble com- nounds that react with the alkaline earths it contains. Hard water and water containing iron also spot and *'rust" clothing washed in it. BOILER WATER. Water used for generating steam should be examined for the pur- pose of forecasting and preventing corrosion, which seriously shortens the Hf e of a boiler, and the deposition of scale, which lowers materially the economy of heat transference. The prevention of foaming in the boUer, important in some places, need not be considered in using most of the surface waters of the Pacific Northwest. CORROSION. The corrosion or slow solution of a metal manifests -itself in boilers as pitting or grooving. As no metal is absolutely insoluble in water, a small, perhaps inappreciable, amount will be dissolved even under ideal conditions. Severe corrosion is caused by the action of acids or, if the boiler metal is nonhomogeneous, by the electrolytic action due to the effect of salt solutions. Severe corrosion due to the presence of organic matter or dissolved gases capable of producing acids, or to the depolarizing effect of dissolved oxygen, may occur even with waters of low mineral content. The substances that cause corrosion are: (1) Dissolved carbon dioxide, hydrogen sulphide, or similar gases; (2) dissolved oxygen; (3) organic matters — ^particularly or- ganic oils — that produce organic acids by decomposition; (4) dis- solved mineral acids; (5) dissolved salts of acid reaction or dissolved salts that are decomposed by heat freeing an acid, such as calcium nitrate, aluminum or copper sulphate, magnesium chloride, and more rarely calcium chloride or magnesium sulphate; and (6) dissolved alkali or other salts that undergo hydrolysis. Corrosion may be inhibited by allowing a thin fibn of scale to be deposited in the boiler, by increasing the alkalinity of the water — - particularly by means of soda ash — by preheating to remove dissolved gases, by generating an electric current to keep the iron of the boiler electropositive, and by making the boiler shell of absolutely pure homogeneous metal. Each method is effective under proper condi- tions, but the means to be employed should be adopted after a study 20 QUALITY OF SUEFACE WATERS OF WASHINGTON. of the causes and the resultant economy. Thus far, however, it has been impracticable to make boilers of pure homogeneous metal. Stabler's formula^ is useful for ascertaining the approximate tend- ency of the dissolved solids in a water to produce corrosion. This formula can not be applied haphazard to the soft waters of Washing- ton, as corrosion with them is less likely to be caused by dissolved soUd material than by dissolved gases or by acids produced by decom- position of organic matter. The computed corrosion factor for such waters as those of Cedar River is misleading, unless it be understood that it refers only to preheated water and that sufficient soda ash may have to be introduced to counteract the effect of organic acids. The amount of carbonate in solution in many surface waters of Wash- ington is probably sufficient to prevent corrosion from such cause. FORMATION OF SCALE. Formation of scale is the deposition of material within the boiler, either by sedimentation of suspended matter or by precipitation of dissolved matter. The scale may vary from soft muck to hard, crystalhne, closely adhering incrustations. Any material that is neither corrosive nor volatile will, when present in sufficiently large quantity, form scale, but as the more soluble substances, such as salts of the alkahes, for example, do not become sufficiently concen- trated to be deposited, scale usually comprises only compounds of the alkaline earths, suspended matter, and colloidal matter. The mineral matter in the surface waters of Washington is com- posed largely of siHca, clay, and organic detritus, which is deposited as more or less adherent crust. The colloidal material includes siHca, iron, aluminum, and organic materials. Silicon may be present as a siUcate radicle in some waters, but it is usually considered to be entirely colloidal silica (SiOg). Deposits of it from most waters are insignificant, but where it forms a large proportion of the scale- forming material as in the waters of Washington it produces a hard, strongly adherent incrustation, very troublesome and dangerous, and removable only with great difficulty. Iron and aluminum are de- posited mostly as hydrates which are converted by heat into oxides, although they may be precipitated as basic salts. They are usually unimportant, but where aluminum sulphate is used as a coagulant in water purification an excess of the reagent hydrolyzing in the boiler may cause precipitation of the hydrate and the formatioji of a strongly corrosive sulphuric acid. Organic matter, especially that of an oily nature, is dangerous, as it either hydrolyzes and corrodes the metal of the boiler or is deposited as a hard varnish-Hke coating that renders the boiler walls liable to overheating. 1 stabler, Herman, Some stream waters of the western United States: U. S. Geol. Survey Water-Supply Paper 274, p. 173, 1911. NATURAL WATERS. 21 The chief scale-forming ingrediejit of most boiler waters is calcium, which is deposited as the carbonate or the sulphate. Few of its compounds undergo hydrolysis, so it can seldom be considered a cause of corrosion. The amount of calcium which can be present without causing serious trouble from scaHng depends largely on the relative abundance of the acid radicles present; much more calcium can be present in a carbonate than in a sulphate water, because pre- heating a calcium-carbonate water precipitates most of the calcium as soft, easily removable sludge, while preheating a calcium-sulphate water removes Uttle scale-forming matter and leaves the water more Kkely to yield a hard, resistant, and troublesome scale. Magnesium is analogous to calcium in its action in a boiler, except that its salts, hydrolyzing under high pressure, deposit the oxide and set free cor- rosive mineral acids. Magnesium carbonate may be formed, but even that salt is decomposed under the conditions in most boilers. Alkaline salts have been stated to form no permanent precipitates, but to undergo hydrolysis and cause corrosion when they are suih- ciently concentrated. As addition of soda ash or other alkaHne salt in water softening increases the amount of alkahes in the softened water and therefore its tendency to foam, it is necessary to deter- mine whether the chemical treatment is likely to remove one objec- tionable feature by introducing another. Bicarbonates are converted by heat into carbonates, which are precipitated in combination with the alkaHne earths. Many natural waters contain enough bicarbonate in solution to precipitate thus the greater part of the alkaHne earths and the addition of reagents for softening is then unnecessary. The carbonate scale from such water is soft sludge easily removable from the heating system by blowing off or by similar means. Carbonate scale is the least harm- ful to boilers and the object of chemical treatment is to remove as much as possible of the scale-forming material as carbonates. Sulphates form hard, compact scale with the alkaHne earths. As It is not economical to remove the sulphate radicle from most waters, it is customary to add sufficient alkaline carbonate to precipitate the alkaHne earths and to leave ther sulphates in equiHbrium with the alkaHes. The quantities of nitrates and chlorides in most waters of Washington are not great enough to make them important m boiler-room practice, though they may act as powerful corrosives under some conditions in highly concentrated waters. FOAMING. Foaming in boilers is the formation of bubbles in the steam space above the surface of the water. If foaming proceeds to such extent that water is forced from the boiler with the steam, ^'priming" is said to occur. The causes of foaming and priming are somewhat 22 QUALITY OF SUEFACE WATERS OF WASHINGTON. obscure, but it seems probable that they may be due to the presence of the hydroxide radicle, as it appears that foaming results when a solution containing a weak acid in balance with a strong base is heated, unless it is prevented by outside agencies. As the amount of alkaline bases in a water is an index of its hydrox^d-producing power, it seems reasonable to adopt the measure of the total alkali bases as the index of foaming propensity, and that is the common custom. Sus- pended matter, not only that normally in the feed water but also that composed of precipitated sludge, and small particles of scale loosened from the deposits in the boder may, however, cause foaming, and it is well recognized that with some waters foaming and priming depend much on the design of the boiler and the manner of its operation. FACTORY WATERS. CHIEF INDUSTRIES AFFECTED. The factories of Washington in which quahty of water has direct bearing on economy of operation or quality of output or both comprise breweries, dye works, ice plants, laundries, meat-packing houses, paper and pulp miUs, soap factories, tanneries, woolen mills, and wool-scouring works. The largest establishments are the paper mills, breweries, woolen mills, and laiuidries. A brief discussion of the use of water and the harmful effects of certain, constituents in each of these industries is presented in the following paragraphs. The reader is referred to any of the standard works on industrial chemistry or the use of water in special industries for more complete discussions of the operations and reactions that are involved. BREWERIES. The water used for brewing must be of great bacterial purity and must contain suitable mineral matter in solution, for it is not only a solvent and a reaction medium throughout the whole process, but forms a part of the finished product. Decomposable organic sub- stances or bacteria are especially harmful, as they mold the barley, lessen the activity of the yeast, and destroy the keeping qualities of the beer by producing offensive putrefaction products.^ Iron forms dark-colored precipitates with the diastase, thus disturbing the con- version of the barley. As it also forms inks with the tannin of the hops, the beer acquires a dark color, a disagreeable odor, and an unpleasant taste. Calcium-sulphate water is desirable for making light-colored beers free from resinous taste, because the calcium sulphate, by reacting with the soft resins C' bitter principle'') dissolved from the hops, produces insoluble resins and thus removes them from the beer. 1 Palmer, Chase, Quality of the waters [of the Blue Grass region of Kentucky]: U. S. Geol. Survey Water- Supply Paper 233, p. 195, 1909. NATURAL WATERS. 23 Water high in alkahne carbonates makes a dark beer, on the other hand, as the carbonates promote the solution of these resins. Light beers are said to have a hop flavor and dark beers a malt flavor, but there is more hop material dissolved in dark than in light beers, the difference in flavor being due to the greater amount of resms in the dark beer and to the blighter solubility of both hop resins and malt in the sulphate water of the light beers. Waters moderately high in chlorides aid the fermentation; but if they are too high in chlorides, development of the yeast, and therefore fermentation, is retarded. Sulphur dioxide for sterilizing the barrels m which beer is shipped is used to some extent; but if other means of disinfection were em- ployed and the keeping quahties of the beer were insured by proper care of the water supply, the general quality of the beer would be higher. PAPER MILLS. Water is used in immense quantities in the manufacture of paper, many mills requiring almost 400,000 gallons of water per ton of product. The water serves as a solvent and a carrier for chemicals, as in digesters and cookers; it conveys the pulp through the various processes; it is the medium in which the wastes are removed; and large amounts are used in the boilers and heaters. The water is usually treated to remove suspended and organic matter, particu- larly Hving organisms. Much suspended matter may cause irregu- larities in texture and appearance of the finer grades of paper, and organic matter may promote algal growths 'that streak and spot the paper and choke screens and pipes. Organic matter also wastes bleach and bisulphite Hquors. Iron is especially undesirable in the water as it deposits from alkahne solutions and spots or streaks the paper. Cross and Bevan ^ state that very soft water is undesirable for loading papers with any form of calcium sulphates, because of the solubihty and consequent waste of these materials in such waters. Dole 2 mentions the probable undesirabiUty of strong chloride waters for the same reason. But very hard water is at least equally objectionable in the chemical process and is much more so for use in making the large amounts of steam that are required in most mills. Hard water deposits calcium carbonate on the screens used to separate the pulp from the hquors; it also interferes with sizing and dyeing, precipitating the resins of the size, and wasting the dyes or changing their actions. The presence of alkah chlorides, on the other hand, is helpful in separating the thick sludge from the size liquor in preparing size. 1 Cross, C. F., and Bevan, E. J., A textbook of paper making. New York, p. 294, 1900, cited by Dole, R. B., in The underground waters of north-central Indiana: U. S. Geol. Survey Water-Supply Paper 254, p. 247, 1910. a Capps, S. R., and Dole, R. B., The underground waters of north-central Indiana: U. S. Geol. Survey Water-Supply Paper 254, p. 247, 1910. 24 QUALITY OF SURFACE WATERS OF WASHINGTON. WOOL-SCOURING, BLEACHING, AND DYEING WORKS. Water in which wool is scoured should be soft, as hard water forms with the grease of the wool insoluble soaps that cling to the fiber and interfere with subsequent processes, thus causing the wool to be of inferior grade, hard "feel,^' poor luster, and uneven color. Very little wool is now bleached, as the natural cream-colored stock is more salable. Wherever wool is bleached, however, it is customary to use sulphur dioxide, which is less injurious to the fiber than hypo- chlorite powder. Sodium peroxide is an effective bleaching agent for wool,^ but hypochlorites can not be used because they would combine with the fiber without destroying the color. Though hard water is required in some processes, soft water is generally essential in economical and successful dyeing of wool. This textile combines with dyes much more readily than does cotton or Hnen, owing to the nitrogen in the wool, and dyeing it is therefore somewhat simpler. The dyes may be of acid, basic, or mordant type. As the reactions involved are deUcate and easily disturbed, and as large quantities of water are used, it is very important to avoid irregularities in its quality that may cause variations in the color of the finished product. In some processes the dye may be precipitated on the fiber by reaction with alkahne earths and thus produce irregu- lar spots. Iron is especially objectionable because it may alter the colors in white and madder dyeing. Chlorides in large amounts are also objectionable, as they may react with the dyes. LAUNDRIES. Hard water causes waste of soap in laundries because the calcium and magnesium in the water form insoluble compounds with the fatty acids of the soap and thus destroy its cleansing value. The alkaline- earth soaps thus formed are deposited on the fabrics and partly decom- posed by heat and thus produce spots on the cloth. Iron is objec- tionable because it gives rise to rusty spots, and suspended matter because it soils fabrics. ' Whipple,^ who has determined by means of nine makes of soap the soap-consuming power of waters of different hardness, concludes that for each part per million increase in hardness about 200 pounds more of soap is required to soften 1,000,000 gallons of water. At 5 cents a pound this represents a loss of $10 per million gallons for each part per million increase in hardness. If his figures are applicable to softer waters than those he mentioned, it would require almost 2,000 pounds of soap to give cleansing properties to 1,000,000 gallons of soft water. Any soap consumption greater than 1 ton per million gallons of water therefore represents waste. 1 Matthews, J. M., Textiles, in Rogers and Aubert's Industrial chemistry, p. 733, New York, 1912. a Whipple, G. C, The value of pure water, p. 26, New York, 1907. PURIFICATION OF WATER. 25 OTHER INDUSTRIES. Hides to be tanned are unhaired by solutions of quicklime. If very hard water is used in that process, calcium carbonate that is deposited on the skins prevents thorough action of the tannin and thus causes spots in the leather. The tannin of the tan bark is not thoroughly extracted and may be precipitated by hard water. Large quantities of chlorides prevent ''plumping'' in the tanning process and make the leather thin and flabby.^ Meat-packing industries use large quantities of water in the wash- ing and preparation of the various by-products, and it is necessary that this water be free from organisms which may grow in and decay the finished goods. Soft water is also preferable, as much water is employed for heating. PURIFICATION OF "WATER. FILTRATION. TYPES OF FILTERS. Filtration of water has long been used as a method of removing sus- pended matter, including bacteria, and of destroying dangerous organic matter. Two general types of filters are used, the ''slow sand" type, in which the water is passed through sand the top layers of which are removed, cleaned, and replaced, as necessary; and the "rapid sand" type, in which filtration is preceded by induced coagu- lation so that the particles to be removed shall be larger, and the water is passed through sand layers which are washed in place at fre- quent intervals. The construction, operation, and efiiciency of many plants of both types and disinfection and similar topics are discussed at length by George A. Johnson in "The purification of public water supplies." 2 SLOW SAND FILTRATION. Slow sand filters have been used for nearly a century and are con- structed in essentially the same manner now as when first built. A series of perforated tiles or pipes connected with a discharge pipe is laid on the bottom of a large impervious basin, now usually con- structed of concrete. Layers of gravel, graded in size from 25 to about 3 millimeters in diameter, are placed over this network to a depth of about 1 foot, and over the gravel is placed a layer of fine sand 2 to 5 feet thick. Regulating chambers, pumps, and sand- cleaning devices are secondary mechanical features of the plant. The filters are roofed where danger from freezing is serious. Where the climate is mild the beds may be left open, in order to lessen cost of construction. The filters are divided into beds usually less than > Rogers, A., Leather, in Rogers and Aubert's Industrial chemistry, p. 798, New York, 1912. * U. S. Geol. Survey Water-Supply Paper 315, 1913. 26 QUALITY OF SUBFACE WATERS OP WASHINGTON. an acre Lq extent, so that units can be withdrawn from service for cleaning without interrupting filtration. During filtration the water sinks through the sand, in which its suspended mud and bacteria are retained, and flows through the dis- charge pipe into the clear-water basin or the distribution system. The rate of filtration, ranging from 2,000,000 to 4,000,000 gallons per acre per day, depends on the physical condition of the filter, the thickness of the bed, the average size of the sand particles, the turbidity of the water, and its temperature. When the loss of head in the filter, as it becomes clogged with shme and detritus from the water, becomes great enough to cause too slow filtration, about half an inch of sand is removed from the top of the bed and filtration is resumed. The sand is washed and replaced before successive re- movals render the bed too thin to be efficient. The time between cleanings is materially shortened when very turbid waters are filtered, so the slow sand process is adaptable only to relatively clear waters or to those that have previously been partly clarified by sedimenta- tion. Color is removed only slightly, hardness is not altered, and slight destruction of organic matter takes place. The efficiency of the filtration depends only partly on the straining action of the sand particles, for it is greater in a filter that has been in service for a short time than in a clean one, possibly because of the absorption of materials as they pass through the coating of gelatinous muck, and possibly because of the colloidal agglutination and also the mechanical straining of the water through the jelly-like mass at the surface of the sand layer. Bacteriologic action in the deeper layers of the bed partly oxidizes the organic matter in the water and prevents further growth of organisms by destroying the available bacterial food. The raw water is usually passed first through strainers, or ''rough- ing filters," or detained m a sedimentation basin in order to remove excessive quantities of suspended matter. Water containing large amounts of iron is troublesome because of its tendency to assist growth of crenothrix, an iron-secreting alga, in the underdrains and discharge pipe. Water containing much iron may be aerated before filtration by being sprayed m fountain-like jets over the raw- water basin, thereby oxidizing and precipitating the iron. At several places, especially in Europe, preliminary sterilization, by ozone, ultra-violet rays, or other means, is practiced. A very high degree of purity is thus attained, but the method is applicable only to clear waters. EAPID SAND riLTRATION. A rapid sand filter contains two essential parts, the coagulation basin and the filter bed. The coagulation basin, generally an oblong tank, is of such size and construction that the water requires PUKIFICATTON OF WATEE. 27 two to four hours to reach the outlet into the filter chamber. Time for sedimentation as well as coagulation is thus allowed. The filter chamber consists of a tank, circular in the early forms but rectangu- lar in the larger modem types, fitted with a perforated bottom, the openings of which are small enough to prevent the sand grains from entering, but large enough to allow ready outflow of the filtered water. On the bottom is a bed of carefidly graded sand, 30 or 40 inches deep and somewhat coarser than that used in slow sand filters. After the water, mixed with the dissolved coagulant, has stood for a proper period in the coagulation basin it flows into the upper part of the filter chamber and passes rapidly through the bed of sand into the drainpipes which conduct it to the clear-water basin for distribution. The rate of filtration is 80,000,000 to 190,000,000 gallons an acre a day, the usual rate being about 125,000,000 gallons. Though several other coagulants are used the most common one is aluminum sulphate. When tliis substance is introduced in solution into the raw water it is immediately hydrolyzed to form aluminum hydrate and sulphuric acid. The sulphuric acid reacts with part of the carbonates, bicarbonates, and hydrates, setting free carbon dioxide and converting temporary into permanent hardness. While the aluminum hydrate precipitated in the alkaline solution as a gelatinous mass is forming and congeaUng, it enmeshes the suspended matter, including bacteria, and absorbs color. If the alkalinity of the water is not great enough to react with all the aluminum sulphate some of the coagulant remains in solution, the eflB.ciency of coagulation is reduced, and the effluent is acid in reaction and consequently corrosive. This trouble is obviated by adding with the aluminum sulphate milk of lime or a solution of soda ash in proper proportion. The coagulant remaining in the water after the imperfect sedimentation in the coagulation chamber forms on the sand in the filter a slime that makes filtration more thorough. As rapid accumu- lation of this sUme causes the loss of head to become excessive, the filter must be frequently cleaned — usually two to four times a day. This is done by passing clean water upward through the sand, and at the same time forcing compressed air through the perforations to break up any agglomerations of sand and dirt. The sand is thus thoroughly mixed at each washing, so that it can not segregate into pockets. The dirty water flows away over the top of the filter. About 4 to 8 per cent of the filtered water is consumed in washing, and the process usually takes from 6 to 12 minutes. Agitation of the sand during washing is effected in some of the older fflters by means of revolving rakes with prongs extending downward into the sand. The rapid sand filter affects the chemical composition of the water to a much greater extent than the slow sand filter. Color 28 QUALITY OF SURFACE WATERS OF WASHINGTON. is greatly reduced, some iron is precipitated, carbonates, bicarbonates, and hydrates are replaced to some extent by sulphates, and the total mineral content may be shghtly increased. If large amounts of lime are added, the hardness and total mineral content are decreased; otherwise the temporary hardness is decreased and the permanent hardness proportionately increased. With filters of this type highly turbid waters can be treated, smaller basins are required than for slow sand filters, and highly colored waters can be partly decolorized. As the method is used chiefly for filtering river waters whose quality is subject to frequent and important fluctuations, its economical operation requires constant and inteUigent supervision. STERILIZATION. Some methods by which sterilization of water for domestic con- sumption has been attempted rely on direct destruction of the bac- teria, and others on their indirect destruction by oxidation and con- sequent removal of their food material, but combinations of the two methods have generally proved most efficient. Calcium hydrochlorite has recently been used with excellent suc- cess to sterilize contaminated water supplies, especially in emergen- cies, and several hundred cities in the United States are now applying such treatment, most of them in conjunction with other methods of purification. The action of the hypochlorite depends on the fact that its solution in contact with the water decomposes to form, first, hypo- chlorous acid, and, second, nascent oxygen. The immediate and chief effect is oxidation, although slower less thoroughly understood reactions^ complete the destruction of organisms. The successful use of this substance and the ease with which its application can be con- trolled place it in first rank among disuifectants of water. If the sodium salt is used the water is softened, but if the calcium salt is used the hardness may be slightly increased; the effect of such change is, however, practically negligible, as the h}'pochlorite is applied in so small quantity.^ The early use of hypochlorite was attended by numerous com- plaints, because lack of definite knowledge regarding the proper quan- tity of reagent resulted in overdoing and thus imparting to the waters a strong medicinal taste or even an odor. Increased knowedge of the process proved that very small amounts of reagent are generally adequate to insure disinfection and that no odors or tastes result when the hypochlorite is properly applied. Copper sulphate ^ has been used more often for the purpose of destroyiug algal growths than for destroyiug dangerous bacteria. Use 1 Rideal, Samuel, Water disinfection by chemical methods: Eng. News, vol. 68, p. 702, 1912. J Johnson, G. A., The purification of public water supplies: U. S. Geol. Survey Water-Supply Paper315, p. 67, 1913. A symposium on the use of copper sulphate and metallic copper for the removal of organisms and bacte* ria from drinking water; New England Waterworks Assoc. Jour., vol. 19, p. 474, 1905, PURIFICATION OF WATER. 29 of it may, however, leave undesirable and even harmful copper salts in solution; alkaline salts may cause waste of the chemical by precipi- tating the copper at the moment of application. The usual method of application — towing a sack of solid reagent around the reservoir — is also crude and expensive. Copper sulphate has nevertheless proved to be a valuable algacide, and it has been decidedly beneficial to some waters. Ozone is theoretically an ideal reagent for disinfection, as the only products of its complete reaction with organic materials are carbon dioxide and water. Considerable progress has recently been made in the use of this reagent, and sterilization by ozone is a valuable adjunct to filtration in Paris, St. Petersburg, and several other European cities. The chief drawbacks have been the expense of manufacturing the ozone and the mechanical difficulties of effecting application with- out wasting the reagent. Ultra-violet rays have been successfully used m Europe to sterilize water, but the process is still in an experimental stage in the United States. SOFTENING. Water is softened for the purpose of removing suspended matter, iron, aluminum, calcium, magnesium, and sometimes sulphates, particularly before its use in boilers. Preheating alone removes enough of the objectionable materials from some waters, but further treatment of others may be required. Many methods alleged to obviate boiler troubles consist in intro- ducing into the boiler with the feed water some '^ boiler compound" and subsequently removing the deposits produced by it. Many so-called ^'boiler compounds" contain, in addition to considerable inert material, tannin or derivatives of tannic acid, which being corrosive are destructive to the boiler. Some containing acetic or other acids are harmful for similar reasons. Others contain organic material, such as glycerin, wood extract, or molasses, whose effects are solvent as that of glycerin, or mechanical as that of molasses. Starchy materials have also been employed. All such compounds are harmful by causing corrosion or even scale production, or by thickening and fouling water in the boiler. In general the introduc- tion of reagents into the boiler is inadvisable and, where such practice is necessary because of inability to treat the supply before it enters the boiler, one or more of the inexpensive chemicals whose action and efficiency have been thoroughly established should be used. Several really efficient reagents are available for softening water and preventing scale, the most widely used of which are lime, as caustic lime (Ca(0H)2), and soda, as soda ash (NagCOg), or more rarely as caustic soda (NaOH). Barium carbonate is very efficient 30 QUALITY OF SURFACE WATERS OF WASHINGTON. chemically for softening some bad waters, especially those high in sulphates, but it and other salts of barium are little used because of their cost. ''Permutite" (an artificial zeolite whose formula approaches 2SiO2.Al2O3.Na2O + 6H2O) and the iron-alum reagents have also been used with reputed success. The softening effect of lime is due to its formation of insoluble hydrates by reaction with certain basic radicles and calcium carbonate by reaction with the free carbon dioxide and the bicarbonate radicle in the water. Lime is not needed in hot treatment, as preheating accomplishes much the same work. Caustic soda, which is some- times used instead of caustic lime, has the decided disadvantage of increasing the total dissolved alkalies and consequently the danger of foaming and priming. It has no real advantage over lime with soda ash, which can be added if desirable. As calcium sulphate is not precipitated by lime alone, soda ash also is used in some waters; it removes the calcium as calcium carbonate, but leaves in solution the sulphate radicle which could be removed by means of barium carbonate if the expense were not prohibitive for most waters. The amount and nature of the reagents for softening water depend on the chemical composition of the water and on the method of treatment. Lime need not be added in hot treatment, as the bicar- bonate radicle is decomposed by heat into free carbon dioxide, which escapes as a gas, and the carbonate radicle which precipitates all or part of the alkaline earths. Some waters produce suflQ.cient carbonate in this manner to react with all the calcium and magnesium and therefore need only to be heated to purify themselves. Waters deficient in this respect may be treated with soda ash before being heated. It is not economical to soften all hard waters. Some waters are so highly charged with incrusting materials that they can not be used profitably even after softening because the foaming ingredients are so greatly increased; others are so slightly miaeralized that suf- ficient scale to iQterfere noticeably with steamiag is not deposited except after long periods of service. Dole,^ citing the findings of the committee on water service of the American Railway Engineer- ing and Maintenance of Way Association, states that it is not advis- able to soften waters containing more than 850 parts per million of nonincrusting material and much incrusting sulphates, but that it is generally economical in locomotive practice to treat waters con- taining 250 to 850 parts per million of incrustants and those con- taining less than the lower amount if a large proportion of the in- crustants is sulphates. An approximate classification reproduced from Dole's paper is as follows: J Capps, S. R., and Dole, R. B., The underground waters of north-central Indiana: U. S. Geol. Survey Water-supply Paper 254, p. 244, 1910. INTERPRETATION OF RESULTS OF ANALYSIS. 31 Approximate classification of waters for boiler use according to proportion of incrusting and corroding constituents. Parts per million. Classification. More than — Not more than — 90 200 430 580 Good. Fair. Poor. Bad. Very bad. 90 200 430 680 METHODS OF ANALYSIS. Daily samples of water were collected for a year or less at each, sta- tion (see list on p. 8) and mailed to the laboratory, where 10 consecu- tive samples were united. The composites thus obtained were anal- yzed in accordance with the general methods described by Dole,^ though some exceptions should be noted. The total suspended matter in waters of great turbidity and high coefficient of fineness was determined by taking from 100 to 250 instead of 500 cubic centimeters of the water. In the determination of alkalies one additional treatment with barium hydrate, followed by treatment with ammonia and ammonium carbonate, was employed in order to insure complete removal of impurities. The final residue was evaporated and weighed in a platinum dish. Fiftieth-normal sulphuric acid was substituted for potassium acid sulphate in titration of alkalinity, as there is no apparent advantage in the use of the acid salt. Besides the analysis of the composite samples, daily determinations of color and alkalinity were made for a great part of the time. Color was estimated by comparing the tint of the filtered samples with that of a series of shaded glasses that had been standardized by means of the usual solutions of cobalt and potassium-platinic chlorides. ^ INTERPRETATION OF THE RESULTS OF ANALYSIS. INDUSTRIAL INTERPRETATION. Formulas for the industrial interpretation of water analyses have been developed by Stabler,"* to whose articles the reader is referred for a full discussion of them. The formulas are as follows: ^=11+1.79 Fe+5.54 Al+2.5 Ca+4.11 Mg4-49.6 H. £=H+0.0361 Fe+0.1116 Al+0.0828 Mg-0.0336 CO3-O.OI65 HCO3. C=0.00833 Sm+0.00833 Cm+0,0107 Fe+0.0157 Al+0.0138 Mg+0.0246 Ca. 1 Dole, R. B., The quality of surface waters in the United States, pt. 1: U. S Geol. Survey Water-Supply Paper 236, pp. 9-26, 1909. 2 Report of the committee on s.tandard methods of water analysis. Am. Pub. Health Assoc, p. 10, New York, 1912. 3 Stabler, Herman, The mineral analysis of water for industrial purposes and its interpretation by the engineer: Eng. News, vol. 60, p. 355, 1908; also The industrial application of water analyses: XJ. S. Geol. Survey Water-Supply Paper 274, p. 165, 1911. 33476*— wsp 339—14 3 32 QUALITY OF SUKFACE WATEES OF WASHINGTON. 2)=0.00833 SiO2+0.0138 Mg+(0.016 Cl+0.0118 SO4-O.O246 Na-0.0145 K). .E;=0.00931 Fe+0.0288 Al+0.0214 Mg+0.258 H+0.00426 HCO3+O.OII8 CO2. i?'=0.0167 Fe+0.0515 Al+0.0232 Ca+0.0382 Mg+0.462 H -0.0155 CO3 -0.00763 HCO3. 2 040 k=~Y^ (when Na— 0.65 CI is zero or negative). fc= -- ' p-, (when Na —0.65 CI is positive but not greater than 0.48 SO4). fifi9 Jc==f;j „ Q^ ^, — n Ao c^r, (when Na— 0.65 CI— 0.48 SO4 is positive). J\a — O.oZ VjL — U.4c) bU4 A represents cost in cents of soap at 5 cents a pound required to soften 1,000 gallons of the water. B represents corrosion coefficient, or relative tendency to produce corrosion in a boiler. Stabler states that if B is positive the water is certainly corrosive, if ^ + 0.0503 Ca is negative no corrosion because of the mineral constituents mil occur, and if B is negative but 5 + 0.0503 Ca is positive, corrosion may or may not occur, the probability of corrosion varying directly with the value 5 + 0.0503 Ca. C' represents the number of pounds of scale which may be formed in the boiler per 1,000 gallons of feed water. D represents, similarly, the number of pounds of hard scale; whence the relative hardness of the scale is -^. E is the number of pounds of 90 per cent lime required to soften 1,000 gallons of water. F is the number of pounds of 95 per cent soda ash required to soften 1,000 gallons of water. Ic, the alkali coefficient, is an index of the value of the water for irrigation; it is the depth in inches of water which on evaporation would yield sufficient alkah to render a 4-foot depth of soil injurious to the most sensitive crops. Fe, Al, Ca, Mg, H, CO3, HCO3, Na, K, CI, SO4, SiO^, CO^, Sm, and Cm represent, respectively, the amounts in parts per million of iron, aluminum, calcium, magnesium, acidity (calculated as hydrogen) , car- bonates, bicarbonates, sodium, potassium, chlorine, sulphates, silica, free carbon dioxide, suspended matter, and colloidal matter (silica, iron oxide, and alumina). The number of pounds of soap (G) necessary to soften 1,000 gallons of the water is obtained by dividing ^ by 5: 6^-2.2+0.336 Fe + 1.1 Al + 0.5 Ca + 0.822 Mg + 0.92 H. This formula practically becomes for most waters of Washington 6^ = 2.2 + 0.5 Ca + 0.8 Mg. The cost of softening with an average soap can then be obtained by multiplying G by the price per pound in cents. In Hke manner the cost of softening by lime and soda ash can be obtained by multiplying E and F by the price per pound of the respective reagents. INTEEPKETATION OF EESULTS OF ANALYSIS. 33 Stabler classifies irrigation waters, in conformity with ordinary irrigation practice in the United States, as follows : Classification of irrigation luaters. ]t. Class, 1 Remarks. More than IS ... Good.... Have been used successfully for many years without special care to prevent alkali accumulation. 18 to 6 ... Fair..... Special care to prevent gradual alkali accumulation has generally been found necessary except on loose soils with free drainage. 5.9 to 1.2 ...I Poor i Care in selection of soils has been found to be imperative and artificial drainage has frequently been found necessary. Less than 1.2 ... Bad 1 Practically valueless for irrigation. Whether injury actually would result from the appHcation of a given water to any particular piece of land, however, depends on methods of irrigation, the crops grown, the character of the soil, conditions of drainage, and quantity and distribution of rainfall, and it should be clearly understood that the alkali coefiicient in no way takes account of such conditions. GEOCHEMICAL INTERPRETATION. The geochemical interpretation of water analyses depends on the geologic significance of the materials entering into solution. The primary rock formations yield water containing a high percentage of aikahes, but sedimentary and metamorphic rocks yield waters con- taining greater proportions of the alkaline earths. Primary forma- tions are usually siliceous and neither chlorides nor sulphates are prom- inent in them. Many secondary formations are rich in salts of these strong acid radicles, though carbonates also are abundant. Solutions of the alkaline materials from silicate rocks are high in carbonates. "When surface waters collect in basins to form landlocked lakes dis- solved matter is gradually concentrated, and salts are precipitated in accordance with their respective solubilities. A great proportion of the alkaline earths is usually removed from the solution during early stages of concentration; in chloride waters, however, magnesium chloride is one of the last materials to be deposited. Lake waters from volcanic regions produce carbonate waters on concentration; those from sedimentary regions may produce sulphate waters, and the final stage of continued concentration and deposition of salts produces the chloride waters, or true brines. Palmer ^ has attempted to establish a system of geochemical classi-, fication of natural waters based on the above facts, and his paper on this subject is an important contribution to the science. His classi- » Palmer, Chase, The geochemical interpretation of water analyses: U. S. Geol. Survey Bull. 479, 1911. 34 QUALITY OF SUKFACE WATEES OF WASHINGTON. fication depends on the relationship between the radicles in waters and the types of rock from which they are dissolved, and, secondarily, on the concentration of the waters. The positive radicles determined by analysis are grouped as (1) alkalies (sodium and potassium), (2) alkaline earths (calcium and magnesium), and (3) hydrogen (free acids). The weak acid radicles (chiefly carbonate and bicarbonate) together are considered to measure the property of '^alkalinity" and the strong acid radicles (chiefly chloride, nitrate, and sulphate) to measure the property of "salinity." As the alkalies are characteristic of the older or primary formations, alkalinity or salinity due to their salts is called primary alkalinity or primary salinity. As alkaline earths are characteristic of secondary rocks, alkalinity or salinity due to them is called secondary alkalinity or secondary salinity. Salinity due to free acids is called ''tertiary" salinity. In applying his classification Palmer has used the reaction coeffi- cients of the radicles, as determined by Stabler,^ which are the quo- tients obtained by dividing the valences of the radicles by their respec- tive molecular weights. The reaction coefficients of the radicles com- monly reported in water analyses are shown in the following table : Reaction coefficients of common radicles. Positive radicles. Negative radicles. Ferrous iron (Fe) 0. 0358 Aluminum (Al) 1107 Calcium (Ca) 0499 Magnesium (Mg) 0822 Sodium(Na) 0435 Potassium (K) 0256 Hydrogen(H) 992 Carbonate (CO3) 0. 0333 Bicarbonate (HCO3) 0164 Sulphate (SO4) 0208 Chlorine (CI) 0282 Nitrate (NO3) 0161 If the amount of a radicle obtained by analysis is multiplied by its reaction coefficient the product is the reacting value of the radicle. The quotients obtained by dividing the reacting value of each radicle by the sum of all the reacting values represent the percentage react- ing values from which Palmer's classification is made. He divides waters into five classes, according to the relative numerical values of the various groups of percentage reacting values. If a, h, and d represent, respectively, the percentage reacting values of the alkafies, alkafine earths, and strong acids, any one of five numerical condi- tions may exist; d may be less than a, equal to a, greater than a and less than a + h, equal to a + h, or greater than a + h. He computes the properties of reaction of each class according to the following formulas: 1 stabler, Herman, The industrial application of water analyses: U. S. Geol. Survey Water-Supply Paper 274, p. 167, 1911. SKAGIT RIVER. 35 Formulas for proper ties of reaction. Class IV. d equal to a+6. 2a, primary salinity. 26, secondary salinity. Class V. d greater than a+6. 2a, primary salinity. 26, secondary salinity. 2 (d—a — b), tertiary salinity (acidity). Class I. d less than a. 2d, primary salinity. 2 (a—d), primary alkalinity. 26, secondary alkalinity. Class II. d equal to a. 2a or 2c?, primary salinity. 26, secondary alkalinity. Class III. d greater than a; d less than a+6. 2a, primary salinity. 2 (d—a), secondary salinity. 2 (a+6— c?), secondary alkalinity. Palmer found that surface waters belong chiefly to the first three classes and that sea water and brines form the greater number in Class IV. SKAGIT RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Skagit River rises in the Cascade Mountains in British Columbia, flows southward between the main axis of these mountains and Cus- ter Ridge across Whatcom County into Skagit County, where it turns westward, flowing first through a narrow and later through a broader valley and fijially discharges through a delta into Puget Sound. It is a navigable stream with shifting bed for about 70 miles above its mouth, but in its upper course it is swift flowing and confined in a narrow bed. The drainage basin includes the region between the main Cascade divide and Custer Ridge, the slopes of the Cascades north of Monte Cristo and Indian Pass, and, through Baker River, the southern slopes of Mount Baker. The most important of the many tributaries are Ruby Creek and Sauk and Baker rivers. Because of its posi- tion in the Puget Sound area and of the character of its basin, the river is unusual even for a stream on the western slope of the Cas- cade Range, for its run-off per square mile is probably greater than that of any other moderate-sized river in the United States. The scanty data regarding the geologic features of the Skagit basin indicate that the northern part is composed largely of schists, slates, and sandstones, probably early Carboniferous in age. Certain out- 36 QUALITY OF STJEFACE WATERS OF WASHINGTON. crops near the Canadian boundary have been classed as Jurassic or Triassic, though the precise geologic series has not been established. The contact between the schist formations and the Tertiary coal measures, which form the surface rock of the middle valley, is near Hamilton. Bodies of limestone near Baker furnish raw material for the cement industry of Washington. The rocks near Marblemount are largely granitic. Sauk River drains an area of slates, shales, sandstones, and granite. The lower valley of Skagit River, well defined where it cuts through the glacial deposits of Puget Sound basin, and its slight slope are indications of advanced maturity. Rainfall in the drainage area ranges from about 40 inches a year near the Sound to more than 100 inches in the mountains. At Monte Cristo, measurements made by the Weather Bureau between 1895 and 1901 recorded precipitation of about 120 inches a year. Precipitation probably is still greater at other places. The upper section of the basin is heavily wooded below the snov/ line. Floods, some exceedingly destructive, are usual in spring. Discharge measurements by the Geological Survey on Skagit River during 1910-11 and gage heights recorded by the Corps of Engineers, United States Arm}', make it possible to compute the variations in run-off as weU as the total discharge for the period of investigation shown in the table of analyses. On the assumption that run-off is 85 per cent of the rainfall, the precipitation estimated from this dis- charge is not less than 85 or 90 inches on the area above Sedro Woolley. The river valley above Marblemount is practically uninhabited. Below this place, at Concrete and Baker, are the cement plants of the Washington and Superior Portland cement companies. Sedro Woolley is the center of the lumber, canning, dairying, and agricul- tural industries of the middle lower valley. Mount Vernon, near the mouth of the river, is the center of an extensive dairy country. Mount Vernon has at times used Skagit River as a source of municipal water supply, but the water at this point is too badly polluted for domestic use without purification. Sedro WooUey is supplied from a small upland stream, whose water is carried across Skagit River through a pipe line. CHARACTER OF THE WATER. Samples of water were collected daily from Skagit River at the Northern Pacific Railway bridge near Sedro WooUey from February 1, 1910, to January 31, 1911, inclusive, by E. J. Woods, bridge tender for the Northern Pacific Railway Co. The gaging station of the United States Geological Survey is at the same place and the drainage area above that point is 2,930 square miles. SKAGIT RIVER. 37 The river water is soft and of good quality for ordinary industrial uses. The small amount of rather coarse suspended matter that it usually carries can be removed by sedimentation for 24 to 36 hours. The use of this water in boilers may at times result in corrosion that may be prevented by the addition of small amoimts of soda ash or lime. The organic matter is the result of the presence of the immense schools of salmon which swim far up the river during the spawning season, and, dying off after spawning, Htter the shores and fill the stream with the products of their decomposition. This organic material may induce corrosion or other troubles in boilers. The excess of sulphate over the alkalies is entirely in accord with what is known of the geology of the basin, for the prevailing rocks are sedimentary and part of the strata is entirely unmetamorphosed. The slight variations in mineralization are shown mostly in chlorine, sulphate, and calcium. The relatively large variations in turbidity correspond to the fluctuations in stream flow. The content of silica is much less than that usually found in waters flowing from lava formations, and it is characteristic of run-off from the metamorphosed Paleozoic rocks of the headwater region rather than that from the later formations of the lower reaches. The rate of denudation in the drainage basin is greater than that of most areas on the western slope of the Cascades. For each square mile of surface drained, 258 tons of mineral matter in solution and 124 tons in suspension are annually carried to the ocean — a total of 382 tons per square mile, or about six-tenths of a ton per acre of land. Because of this high rate of erosion soil is practically lacking in the steeply sloping parts, the little that exists being held in place by the matter roots and fibers of the forest growth. Destruction of forests in the mountainous regions will quickly be followed by exposure of the rock surface over large areas, and drifts or eddies of soil will remaia only in the hollows and crevices. The determinations of the color and alkalinity of the water, made on samples collected daily from March 13 to June 15, 1910, inclusive, show the daily fluctuation only during flood stages, and therefore are more irregular than the determinations of the average fluctuations for the year would indicate. The water is not highly colored for spring- flood water, doubtless because no great amount of humus material accumulates in the mountains during winter to be washed into the streams during spring and summer. The alkalinity is so low that small amounts of soda ash or lime would probably have to be added at times if coagulants or hypochlorites were used in purifying the water. 38 QUALITY OF SUEFACE WATERS OF WASHINGTON. u . ^ « ft. 0-r< C3 fl c3 OOOOOOOOOOOOOOOOOOOOiOiOiCOOOOOOOOOOOOOO C^t>.00O(M'-i'— i'-HN500>OCOCOt^O-^I>-'-II^OCO'^t-~-^COC^'— lTrc>5iOOC<)i— lOcj^H 00'«*'OOCOOOOOr^f0050-l,-l,-l'-',-( r7^ d C3 C 53 i^. «51r^»0OOOOOOOOOC>OOOOOQOi-l«0<-ic0OO00OOOOO0000O-*c£> C0050MOOl30'-l-¥ ■^C<)OOl-->-i-*Ot~»»0C0"5O»Ot-"^-*'— li— (iOiO'^00O5-<*'r-(i-IO5O3000Q'-HiOt~-O00f'5>O»OOM0000 ^26 © o .-oooooooo CO Soooooooo ^-050^^S^-Ooo^iioa3o:=i©«;::;©--HO'^oqX'-H'*ooc;030co«50>.';c<)OC53C03--i(Nin ^ ft ooooooooooooooooooooooooooooooooooooo COi-IO-^C<»021>-OOCi'-HiC—OOC0010—IMOC<)01t^(NOOOOOOCO-*0005 ooo P4 ^ CO 8B6 ■So ^. « s ^ 'C (-1 I C © CO p-3 -i^ Hi O cl ^1 Tj< -rf -^ 00 ^odo6o6ojO'--l lOlOO0 1-1 O ■*! CO CO 00 »0 rH 05 CO C<1 »0 05 "5 ■* »o o>oico6cot>^"*ooc5-^-^»ot^-*i>^cococ6c6cocoooJoc-^cot>^j>^cocot~^t>^t-^05050ci lr-ll-l(M.-l rt.-(r-H(M' T— )*-Hr— (T-H C<|i— I»-Ht-H tHi (N coco ■* lO 00 00 ■* ^ o ® o3 ft 3 3 P ft -C3 tX © ft WOOD CREEK. Color and alkalinity of the water of Skagit River at Sedro Woolley. [Parts per million.] 39 Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar. 13 . .. 14 16 14 20 22 14 16 54 8 8 7 6 4 5 11 7 8 8 4 4 10 16 17 9 9 9 8 8 8 6 10 8 0.0 .0 .0 a 2. 2 .0 a 8. 4 .0 .0 .0 .0 .0 .0 a 1.4 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 ol9 a 3. 8 a 13 a 4. 6 a 14 a 17 .0 a 7. 2 .0 .0 .0 30 26 24 33 24 28 31 46 31 27 29 29 36 37 35 32 32 34 33 48 29 36 30 33 35 23 14 18 17 21 28 28 34 1910. Mav 7 8 6 8 8 16 16 20 15 12 16 12 14 16 8 8 6 8 10 10 16 16 12 12 10 6 8 6 10 8 14 40 36 34 30 ol4 .0 .0 06.0 .0 .0 .0 .0 .0 .0 a 14 a 7. 7 a 3.1 a 6. 2 .0 .0 .0 a 4. 3 .0 a2.4 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 13 14 8 23 15 9 23 16 10 13 17 11 18 19 . .. 12 18 20 - .. 13 23 21 14 23 22 15 24 23 16 24 24 17 8.5 25 18 20 26 19 29 27 20 23 28 . . .. 21 24 > 30 22 23 31 23 20 Apr. 1 24 23 3 25 24 12 26 - 28 27 13 34 14 31 32 15 June 1 21 16 2 26 25 3 23 26 4 23 27 5 24 28 6 21 29 8 30 30 9 23 May 1 10 22 2 12 15 3 13 18 4 14 21 5 15 22 6 a Abnormal; probably present as HCO3 at time of collection. WOOD CREEK. GENERAL FEATURES OF DRAINAGE BASIN. Wood Creek is a small stream that rises in the hills south of Everett and flows into Snohomish River. Its drainage basin, uninhabited and completely forested, is deeply covered by glacial drift. The stream is swift, its valley is naiTow, and its discharge is small but widely variable. The creek is important only because with two small streams floT^-ing from the same uplands it forms the water supply of Everett. CHARACTER OF THE WATER. Samples of water were collected daily from the creek at its point of discharge into the impounding reservoir of the city of Everett through the courtesy of Dr. A. P. Duryee, city health officer. Though the water is moderately hard, the hardness is mostly tem- porary and can be removed either by preheating the water or by treating it ^^'ith small quantities of milk of lime. Treating the water 40 QUALITY OF SUEFACE WATEES OF WASHINGTOK. for boiler use, however, is not advisable as the amount of scale- forming matter is so small. The water is characterized by primary alkalinity, which indicates that the prevaiHng rock material is of igneous origin. This fact is important as the underlying formations of this part of Puget Sound basin are supposed to be sedimentary rocks of Tertiary age, though the evidence of the water analyses indicates that the great blanket of glacial drift was derived from the intrusive or effusive rocks of the Cascade Range, not from the sedimentary rocks of the valley floor. Mineral analyses of water from Wood Creeh near Everett, 1910-11. [Parts per million unless otherwise stated.] Date. >. -f.^ 4. h a o M ^ a d ■2o -6 IS . 1 ©o m 1 From— To— '2 u .2fl o O m a' '3 •i-i w OQ .0 -e.s ft 02 03 I > s Mar, 13 Mar, 22 10 15 1.50 26 Trace. 7.2 5.2 13 «13 34 6.1 Trace. 2.5 86 23 Apr. 1 25 44 1.76 37 0.01 8.6 3.8 8.2 .0 54 14 Trace. 106 Apr. 2 11 20 28 1.40 20 Trace. 8.5 4.4 7.6 .0 43 7.9 Trace. '2.'5' . 75 12 21 25 26 1.04 26 Trace. 9.4 4.6 8.5 .0 56 8.9 0.40 3.3 94 22 May 1 5 5.2 1.04 26 Trace. 9.0 4.4 7.6 .0 51 9.8 .20 3.5 87 May 2 11 50 51 1.02 .02 8.2 3.9 7.2 .0 51 11 .50 2.5 54 12 21 20 38 1.90 27 Trace. 8.2 4.2 7.9 .0 52 9.5 .00 2.8 91 22 31 5 4.0 .80 27 Trace. 8.5 5.2 8.0 .0 51 7.9 Trace. 3.0 90 June 1 June 10 15 20 1.33 23 Trace. 9.0 5.2 8.8 .0 57 8.9 Trace. 3.0 91 11 20 15 21 1.40 35 Trace. 11 5.0 9.8 .0 61 7.2 Trace. 3.3 107 21 30 10 14 1.40 19 Trace. 9.8 5.6 8.8 .0 56 7.7 Trace. 2.8 81 July 1 July 10 50 43 .86 41 .01 11 3.5 10 .0 55 8.9 .00 3.3 119 11 21 20 30 7 13 1.86 26 Trace. 8.8 8. 7 .0 52 12 90 5 2.4 .48 23 Trace. 9.2 *5.'2' 7.6 .0 55 6.9 "".'66' '3.' 6' 83 31 Aug. 9 7 5.8 .83 27 Trace. 9.0 6.7 8.0 .0 57 6.9 .45 2.6 94 Aug. 10 19 15 11 .73 21 Trace. 9.3 5.0 8.4 .0 49 7.1 Trace. 3.3 82 20 29 2 1.4 .70 28 Trace. 9.6 5.2 7.6 .0 54 7.6 1.9 3.2 90 30 Sept -8 15 13 .87 25 .01 8.0 4.6 7.8 .0 57 5.1 .00 3.1 82 Sept. 9 18 5 3.4 .68 21 .01 10 3.6 8.2 .0 54 6.9 Trace. 3.5 86 19 28 Trace 21 .01 9.2 4.4 10 .0 63 5.3 .65 2.8 101 29 Oct. 8 5 3.7 '"."74" 18 .05 7.1 4.8 6.7 .0 50 6.6 Trace. 2.5 85 Oct. 9 18 3 1.8 .60 30 .06 7.2 4.6 6.9 .0 50 5.0 . 75 2.8 85 19 28 5 11 2.20 28 .06 8.6 4.8 7.2 .0 50 12 .63 3.3 89 29 Nov. 7 2 1.6 .80 30 .07 7.2 4.4 6.1 .0 48 6.5 - .75 3.0 86 Nov. 8 17 4 1.7 .42 29 .03 7.7 4.4 6.5 .0 50 5.4 .70 2.5 83 18 27 1 .8 .80 26 .05 8.8 4.8 6.8 .0 48 9.7 2.0 2.8 87 28 8 18 Dec. 7 17 27 3 2 3 26 27 15 .01 .01 .03 7.6 7.6 6.8 5.0 4.4 4.2 5.7 4.9 6.7 .0 .0 .0 49 48 48 6.9 6.9 7.6 .50 .10 Trace. 2.5 2.8 2.1 84 Dec. ;;;;;;i ; 80 .7 .23 83 28 Jan. 6 2 6.0 3.00 22 Trace. 7.7 4.2 6.1 .0 45 6.9 .05 2.6 78 Jan. 7 16 3 7.1 2.37 24 .01 6.9 3.6 5.6 .0 42 5.6 Trace. 2.5 73 17 27 26 31 3 3.0 1.00 20 Trace. 9.6 3.5 6.8 .0 39 8.6 73 4 2.8 !70 16 .01 8.2 2.8 5.7 .0 37 5.3 '"'.'io' '2." 8' 65 Mej mtai m 10 rous re 13 sidue. 1.15 25 30.6 .01 .0 8.6 10.5 4.5 5.5 7.6 9.3 .0 30.7 51 7.8 9.5 .31 .4 2.9 3.5 86 Percf jeofan iiyd a Abnormal; computed to HCO3 in average. CEDAR RIVER. GENERAL FEATUHES OF DRAINAGE BASIN. Cedar River rises on the western slopes of the Cascade Mountains near Yakima Pass, flows northwestward through Cedar Lake, and, after following a general westerly course, unites with White River near Renton to form Duwamish River, which enters Elliott Bay on CEDAR RIVER. 41 Puget Sound south of Seattle. In its upper course Cedar River flows through rugged, heavily timbered country, from which it emerges a short distance above its junction with White River. In the Cascade Mountains the river flows over exposed metamor- phic and igneous rocks (largely andesites with some basalts and rhyo- lites), but lower down it traverses outcrops of Tertiary sandstones and shales that include coal seams. Near its mouth it flows over the deep glacial drift that overUes bedrock around Puget Sound. Annual precipitation in the basin ranges from less than 40 inches near Puget Sound to more than 100 inches on the mountains. The winter precipitation in the mountains is chiefly snow; in the lower valley it is principally rain. The snows remain unmelted on the mountains during winter, except when a chinook wind induces sud- den and usually rapid thaws. When this occurs the river is in flood, and if the chinook is accompanied by heavy rains the freshets may become violent. Spring floods are caused by rains and melting snows, and still another period of high water is caused by autumn rains. The water supply of Seattle is taken from Cedar River below Cedar Lake near Ravensdale. The drainage from the main line of the Chi- cago, Milwaukee & St. Paul Railway, which skirts the river for sev- eral miles above the intake, is either filtered through thick beds of graded filtering material or carried into the near-by drainage basin of Snoqualmie River by a carefully planned system of ramparts and drains. Special regulations also prohibit the deposition of any train wastes at any place within the watershed. In addition to this pro- tection the Seattle water department employs a regular system of patrol over the basin to prevent trespass by campers, hunters, or tramps. The city has recently taken steps to purchase by condemna- tion the small part of the drainage area still privately owned, so that the whole area tributary to the river above the intake may be con- trolled by the city, thus insuring for all time a pure water supply.* The supply is conveyed to the city through a pipe line emptying into a reservoir at Volunteer Park, which crowns a high hill in the heart of the city. The annual consumption is about 13,780 milhon gallons, or 160 gallons per capita per day.^ Though Seattle is built around two fresh-water lakes — Lakes Union and Washington — as well as on Puget Sound, only an insignificant part of the water used in local industries is obtained from these sources. According to the United States census the population of Seattle in 1910 was 237,194. The prmcipal industries are lumber milling and shipping, although several breweries, as well as car shops, machine i See also Freeman, J. R., Chances of pollution of Seattle water supply: New England Waterworks Assoc. Jour., vol. 20, p. 464, 1906. Possible pollution of Seattle water supply (anon.): Eng. News, Aug. 30, 1906. « Personal communication in 1911 from Mr. John Lamb, of the Seattle water department. 42 QUALITY OF SURFACE WATEES OF WASHINGTON. shops, foundries, paper mills, brick and tile works, gas works, and others are located there. The city's importance results chiefly from its commerce, but manufacturing is rapidly increasing. Kenton is the only other important town in the basin of Cedar River. Its principal industries depend on near-by coal mmes, although it also has a brick works, a car manufactory, and a glassware factory. CHARACTER OF THE WATER. Water from Cedar River near Ravensdale was collected for this investigation by Mr. George Landsburg, through the courtesy of the board of public works of Seattle. As the daily samples were taken from the running water above the dam at the intake of the Seattle waterworks, the suspended matter normally carried by the stream is included. Sedimentation in Cedar Lake decreases the amount of material carried m suspension to some extent, but as the upper stream is usually clear, the effect is slight. The stream-flow data in the table of analyses are compiled from the records of the gaging station at the dam. The drainage area above the station covers 149 square miles. ^ Discharge is somewhat regulated by the storage of Cedar Lake, but seasonal variations are nevertheless pronounced. Cedar River carries little suspended matter, and sedimentation above the dam and in the distribution reservoirs at Seattle keeps the city supply free from unpleasant turbidity except at times of excep- tionally heav}' rains and rising water. Dissolved mineral matter also is small in amount, rangmg from less than 30 to little more than 80 parts per million. The content of silica, which shows the greatest variation, 'may be materially affected by algse and diatoms in Cedar Lake and in the sluggish water above the intake dam. Silica in- creases during storage of some samples after collection, and it is therefore permissible to consider unusually high estimates of silica abnormal; yet the average, 13 parts per million, may be regarded as accurate within the ordinary limits of analysis. The marked daily variation in content of chlorine is often greater than the amount which would be added to the water by a population of many thousand people on the drainage area, so no normal value of chlorine can be established from analyses of this water. The water is calcic carbonated in type, and is admirably adapted for all household uses. It does not foam in boilers and deposits only a slight amount of scale, which differs somewhat in texture from day to day but is usually rather hard. As the scale is siliceous no im- provement in that respect can be obtained by treatment with soda ash or lime. It is known that free carbon dioxide and oxygen are some- times present in large amount though no determinations of them 1 Henshaw, F. F., and Parker, G. L., Water powers of the Cascade Range, pt. 2: U. S. Geol. Survey Water-Supply Paper 313, p. 103, 1913. CEDAR EIVER. 43 were made during this study. Owing to the presence of these two dissolved gases, one a solvent and the other a precipitant by virtue of its oxidizing power, service pipes are frequently corroded and rust is formed, so that it is not unusual for the first flow from taps in Seattle to be red. This condition, which is not at all unusual for waters coming from regions similar to that around the headwaters of the Cedar River and is aided by the low mineral content of the water, can be overcome by artificially hardening the water by the addition of lime. The exact amount of the reagent necessary at any time can be ascertained only by analysis of dissolved gases, but enough should be used to add about 10 or 15 parts per million of lime (CaO) to the water. This would not render the supply unduly hard for use in boilers. Color and alkalinity were determined on daily samples of water from Cedar Ki^^er at Ravensdale from March 6 to July 14, 1910, inclusive. The water was usually colorless or nearly so and the alka linity was small. If filtration were adopted the water could advan- tageously be passed through slow sand filters, on account of its soft- ness and its freedom from color or suspended matter. The alka- linity, which is sometimes too low to insure proper precipitation of coagulants, would then be a matter of indifference. 44 QUALITY OF SURFACE WATEES OF WASHIITGTON. I O) (D (/3 • K)r7-J +J r] t< V" C^0s-^-^'-IC0'0OC0«0>-liCi'-l lO OiO CD e<5 1-1 -^ 1-H .-I CO ■* •* 00 CO (M rH t>- i-icqrH e Q • OOTHCOC<100M<5'Cfl^COCOlOCOlOT-IOCOCO(NWCcoo^ocooa505'-Hooo5^©^o■^coco(^^(^^l^^'--lr-^(^^(^^(^^(^oco■*■*^o^ooo^:^^ccooo^o•* <0^ O 05coooow^c«5eQOOi-H(Mco(Moc i-< 1-? ' ' 1-H * ' ' tA ' 1-5 rH T-i -^ tH tH i-4 i-5 rH rr^ tH i-i tH t-5 i-J i-J rH r-J i-H (M CO c3 O^ Ene e^ en 000 c3 c3 (^ !-i ^ ;-i Tt«0(N>OT(<-^OOOCO'*COt^cDcO>0(NOOC00505 ^-^^>^C0CO^0CO^O'O^O^O^OCOO5lOC0"5C0COC0'^lO00^~O5'Ol^■^•^cO(»lOTi^^ 10 c4 I 0) ® 'Tj Sets «0 w. !W g^ 000000 0000000000000000000000000000 go rs ft S m^ O fl ^ C3 t^COOOOOiOfOCO(NCOOi-HiOOO(N0001(NT-iOOT-IOOOOO'5»Ot^t~«e«305'*iOC-OT-Hi-IO«DlOOJ C^ rH rH rH t-5 tH T-H rH r-i 1-1 1-H rH -'*cO(MCOOOO(NC^OOOt^'<*iC<5005Tt^odt6odc~^t^^-^^cDc6cOlOTt^^d^ocd^^cd^>^ 1-H 00 O 10 10 05 O 1 7: -i-(oooou5cot^eqo»ciiMO":ii-HO!MMt^fO>o 00 T-l CO CO 0> CO O "* 1-H CO !>. (M O >0 lO 1-H r^ 1-H id co> t^ "3 CO CO 1-5 pR S <1 S 3 S^ g^ t^ 5 § g ►? -^ ra o ;2; fi .? Ph a <«j a »^ ^ s § tj ^ S d < ^ O ^ Q ^ ^ -g :i . o B ® « C3 1^ ID ps GREEX EH^EK. 45 Color and alkalinity of the water of Cedar River at Ravensdale. [Parts per million.] Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar 6 4 4 6 7 16 8 12 8 7 8 8 8 4 4 4 4 4 4 6 8 2 2 0.0 .0 .0 .0 '.0 .0 al.9 al8 .0 .0 a4.1 .0 .0 .0 .0 "1.7 .0 .0 .0 "2.4 .0 °S.6 "9. 1 "8.4 .0 .0 020 al6 a 19 04.8 a2.2 24 33 28 27 34 28 30 16 22 23 20 26 27 24 24 25 26 24 22 23 21 13 13 13 27 < 22 .0 1 .0 25 34 1910. May 22 2 55 2 4 6 2 8 2 4 7 8 8 7 5 5 4 16 8 4 8 4 4 8 8 8 8 6 a6.0 a7. 4 a6.0 .0 .0 .0 .0 al.4 04.6 .0 .0 04.8 .0 .0 .0 .0 a4.8 .0 .0 .0 .0 .0 .0 al3 02.4 .0 .0 .0 .0 .0 .0 24 23 21 8 24 21 9 26 28 10 27 22 11 28 23 12 29 24 13 30 36 14 31 29 15 June 1 24 16 2 26 17 3 26 30 5 33 31 19 28 Apr. 1... - 20 43 2 22 34 3 23 28 4 • 26 31 6 27 30 8 ! 28 31 9 1 29 30 10 July 1 11 9 33 12 3 22 13 4 33 17 5 40 18 10 31 19 11 33 20 12 38 May 20 13 32 21 14 34 a Abnormal; probablr present as HCO3 at time of collection. GREEX RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Green River rises near Stampede Pass in the Cascade Mountains, in King County, flows in general northwest, and joins White Eiver near Auburn. In its upper coui'se, above the point where samples for this investigation were collected, it drains an area whose rocks are almost entirely andesitic. Some basalts and rhyohtes are found, as are also small amounts of tuff, but pyroxene andesite and dacite form the main portion of the surface rock. CHARACTER OF THE WATER. Samples of water were collected from Green River at the bridge near the hotel at Hot Springs daily from February 1 to August 18, 1910, inclusive, by J. M. Corcoran. Forest fires, which devastated the valley and destroyed all habitations at this place, forced the discon- tinuance of the station in midsummer. Xo discharge data for Green River are available. The water is typical of rivers draining areas in which the rainfall is large and the surface formations are Tertiary andesites. The con- tent of magnesium is less than might be expected. Though the 46 QUALITY OF SURFACE WATEES OF WASHrXGTOX. average content of calcium is only 1.1 parts per million less than that of Crater Lake, Oreg./ where andesites also predominate, the con- tent of magnesium is l.o parts per milhon less, and the calcium-mag- nesium ratio, which is 1 to 2.5 for the water of Crater Lake, is 1 to 4.6 for the water of Green Kiver. The water is suitable for industrial use without treatment. It is nonfoaming, but will deposit small amounts of hard siliceous scale. Though true corrosion from such waters is unlikely, burning and resultant pitting may occur beneath the silica scale if boilers are improperly managed. Green Eiver receives pollution from many sources along its entire course and below the village of Lester can not be considered a safe source of domestic supply without purification. Tacoma has recently constructed works for the utilization of the water of Green River as its municipal supply. Mineral analyses of water from Green River at Hot Springs, 1910. [Parts per million unless otherwise stated.] Date. i i "tc ■r. ■fi ~ "a jo Dl "^ ~ ^ ^ % "c^ ^ ^ ^ ^ 5C . 2 From— To- ■ 1 ft ES 'X. o S O m m i i— 1 o a a o r ^ en 1 ■A m 2 . 1 if ^]3 i i CO 1 on CO 5 Feb. 1 Feb. 10 3 2.6 0.87 17 0.11 5.4 2.0 0.0 25 12 0.45 2.5 58 11 20 3 1.6 .53 18 .04 6.5 1.3 ""6.'9' .0 29 10 .10 1.0 57 21 Mar. 2 10 •6.0 .60 35 .26 6.8 2.1 11 .0 51 8.6 .30 1.4 109 Mar. 3 12 4 16 4.00 6.6 .06 5.9 1.5 6.6 Trace. 24 8.9 .00 1.3 56 13 22 10 25 2.50 16 .05 4.8 1.9 8.2 .0 26 10 .00 1.0 51 23 Apr. 1 8 6.3 .79 9.2 .06 4.1 1.0 3.5 .0 20 3.7 Trace. 1.3 39 Apr. 2 11 9 6.2 .69 14 .02 5.4 1.7 7.1 .0 24 6.1 .10 1.0 50 12 21 10 8.9 .89 13 .04 4.3 1.3 6.6 .0 29 5.3 .35 1.3 60 22 May 1 8 6.7 .84 il5 .01 5.3 1.0 5.4 .0 27 6.5 .50 1.5 44 May 2 11 10 9.6 .96 20 .01 6.0 1.4 4.0 .0 25 3.2 .30 1.0 56 12 21 5 5.2 1.04 25 .01 5.4 1.2 3.3 .0 27 2.3 .50 1.0 56 22 31 5 3.3 .66 20 .01 5.3 1.2 4.5 .0 23 5.2 .00 2.0 55 June 1 June 10 15 11 .73 IS .01 5.6 1.3 5.6 .0 30 6.1 .00 1.0 65 11 20 10 9.6 .96 12 .01 7.3 1.1 5.0 .0 29 3.6 .00 1.0 43 21 30 5 4.4 .88 23 .01 6.0 1.4 6.0 .0 27 3.5 .00 .8 58 July 1 July 10 4 3.3 .83 17 .01 7.2 1.3 5.1 .0 31 4.9 .00 1.3 54 11 20 5 9.1 1.82 17 .01 6.1 1.0 5.1 .0 28 6.4 .00 1.3 55 21 30 3 2.9 .97 12 Trace. 8.5 .9 4.7 .0 34 3.4 .00 1.5 51 31 Aug. 9 1 0.4 .40 11 Trace. 6.8 .8 3.5 .0 29 3.6 .00 1.8 45 Aug. 10 ean. . . IS 1 1.0 1.00 12 Trace. 7.1 .8 4.1 .0 28 5.2 .00 1.8 48 M 6 7.0 1.10 !l7 .04 6.0 1.3 5.6 .0 2S 5.9 .13 1.3 55 Percenta ge of anhy drou sresid ue '33.3 a.l 11.7 2.5 11.0 27.0 11.6 .3 2.5 a FeoOj. CHEHALIS RIVER. GENERAI. FEATURES OF DRAINAGE BASIN. Chehalis River rises in the Coast Eange in Lewis County, flows northeastward to ChehaUs, then northward for a short distance, and finally northwestward to Grays Harbor, through which it passes to the Pacific. At Chehalis it is joined by Xewaukum River, and at 1 Van Wiiikle, Walton, and Fintbiner, N. M., Composition of the water of Crater Lake, Oreg.: Jour. Ind. and Eng. Chemistry, vol. 5, p. 198, 1913. CHEHALIS EIVEK. 47 Centralia by Skookemchuck River. Satsop, Wynoochee, and Whi- shah rivers, its most important tributaries, enter in its lower course. Its valley is broad and the general elevation of the headwaters is not great. Much of the basin is covered with a good stand of fir and other conifers, and lumbering is an important industry in the valley. Sedimentary rocks of Tertiary age, overlain by Quaternary marine deposits are probably the chief formations of the region. The Ter- tiary rocks include extensive beds of lignitic coal which is almost useless for steaming but valuable for gas production. CHEHALIS RIVER AT CENTRALIA. CHARACTER OF THE WATER. Samples of water were collected daily from ChehaHs River at the bridge near Centraha by John Arveson, from February 1, 1910, to January 31, 1911. A gage was installed at this point October 3, 1910, and approximate estimates of daily discharge have been made from that date until the end of the samphng period. The water is soft, usually turbid, and subject to frequent and great changes in its content of dissolved matter. The content of chlorine, which is noticeably greater than that of water from most of the other streams, is due largely to solution of saline matter from the sedimentary rocks of the basin and to wind-borne salt from the Pacific Ocean in the rainfall on the coastal mountains. Sulphates form about 11 per cent and carbonates about 26 per cent of the dissolved matter. The water is suitable for use in boilers if it is first clarified. It wiU deposit smaU amounts of hard scale and might also become corrosive under some conditions of service though it ordinarily re- quires no treatment. As it contains large amounts of organic matter and is grossly polluted with sewage, it is unfit without purification for domestic use or for any use requiring potable water. Color and alkalinity were determined in the samples collected daily from March 16, 1910, to January 26, 1911. Many of the marked variations in alkalinity can be traced directly to changes in stream flow. Sometimes, as on October 17, 1910, the rainfall was accompanied by a temporary increase in alkahnity, probably caused by increased solution of surface material during gentle rain. Nearly always, however, rainfall and consequently in- creased stream flow was followed by decrease of alkalinity — an effect of dilution. Alkalinity gradually increased with falling stage of the river until July 22, when it dropped suddenly, then increased grad- ually until July 29^ when it once more dropped. No rain fell at Centralia during July, but precipitation occurred at various places in the Cascade and Olj/mpic region on July 21 and 22, and another 33476°— wsp 339—14 4 48 QUALITY OF SUKFACE WATEES OF WASHINGTON. slight rainfall was recorded in some localities on July 28 and 29. The drops in alkaUnity evidently reflect the rainfall in the upper part of the basin. The determinations of alkalinity occasionally show normal carbonates that probably resulted from reactions after the samples were collected. Experiments made by the writer on waters from ChehaUs River showed that one of the most marked changes during standing is a gradual loss of bicarbonate and equivalent gain of normal carbonate. The absorption of carbon dioxide by organic matter may influence this change. The water is usually highly colored, and appears decidedly brown at times even in small bulk. Whether some of the color is caused by colloidal suspended matter in tht nature of carbon from coal whether it is of peaty origin, or whether it was entirely algal is not known. The fact that strong color is synchronous with great tur- bidity is circumstantial evidence that the color is due to peaty matter, for the peat swamps overflow into the river during floods and thus deliver to the stream large quantities of highly colored water. CHEHALIS RIVER. 49 e>«0'OcoiOTf<-»» (i> en • w3 -u c fr! »». 5 11^^^ •*(rOO<00(M05-i >-i -H Ti< c3 OQ (I S +j «;r5 c3 § OJ '^ O CO "^ ?omo»o>ot^ooc<»ooc>3co-* rt"l--^T-^~lr^^-^^f(^^l^^l^^c<^l^o(^^ oooioicoooioomo OOCSlOlCt^COMOOt^O'^CO I^C005000t~i-IO>— ICOIO-^ ."2 "5 S.So COiO'-ic->OCOOOCO(MO»00-iOCOcOOOOO»0 o>ld^^»ood■*'»OlO^-^dcDcot>^o^^o■^•^t^cco6^-^lO■^<»kCTr^■<15cocc^orj3^o ^ d cataaC .2 a 'So m. la ( c« eq (N c^ 0(MIOO-*IM t~- «0t-C00005O->*i««D00-*00i-it^i0 •ooo>oo-<*'c<5ooe^ 1-1 eo O ■* 0> C33 -^ 05 O CO CO C^ 00 »0 O --H C^ r-l r-l >0 rH Tf Tf -^ C^l -H CO 00 1-I ■* «0 I-H CO O iO'0OC^»iC rH 000 00000 * SOIM SOOO 5^OOOOT-lrHOO »o 10 ^s Ph O(NC><>-ti-i--i.-i.-(i-ii-iOpOOOOO3O»0»0000000000apt^h-t^t~t^t>.«0«OC0r-i 1-1 1-1 c» i-i(N ^ e^ C0 1-1 e^ CO i-( e>< CO ^ ?« i-i cs i-i ?5 i-i c« i-i c< i-i c<» co <1 2 >^ 3 ^ <1 Q< A ^ a r" 3 3 3 ■ T3 • >. :a • s . (fl • *-. • q i> d be <» OS « 'a PM 50 QUALITY OP SUKFACE WATERS OF WASHINGTON. Color and alkalinity of the water of Chehalis River at Centralia. [Parts per miUion.] Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar. 16 16 16 12 20 16 24 32 20 20 14 14 16 16 12 14 8 20 32 36 32 30 36 36 62 48 16 .24 14 10 14 10 12 54 8 12 10 12 14 16 14 9 14 14 16 8 8 10 8 16 15 15 14 9 15 17 15 14 16 15 0.0 .0 .0 .0 .0 .0 .0 04.1 .0 .0 00.7 a3.8 .0 .0 .0 .0 .0 .0 .0 .0 ol.O .0 .0 .0 .0 a5.0 .0 .0 .0 .0 .0 .0 00.2 .0 al4.4 .0 .0 0I2.O a7.2 a7.2 ai.S all. 8 9.8 0I5.6 .0 .0 .0 .0 .0 al9.2 .0 .0 .0 .0 .0 .0 a28.0 .0 06.0 .0 al4.4 al6.3 a5.8 .0 a8.2 al2.0 .0 .0 aTrace. .0 .0 a3.1 .0 .0 .0 22 43 23 36 23 . 24 23 30 23 28 39 36 32 26 29 27 34 25 22 21 37 30 21 18 19 13 21 25 23 25 21 24 15 26 14 31 30 16 32 15 21 9.8 9.5 11 30 30 32 34 27 1910. June 6 9 8 17 8 15 16 8 16 8 18 21 16 17 16 16 16 16 13 11 15 16 17 17 16 8 32 16 16 16 17 19 16 8 15 8 8 9 16 16 17 16 16 8 6 14 16 16 16 17 16 16 16 16 16 8 16 15 14 16 16 16 15 16 26 15 16 16 16 16 16 16 16 15 16 16 16 0.0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 o2.4 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 a7.2 .0 .0 .0 .0 35 17 7 43 18 8 38 19 9 43 20 10 42 21 11 22 12 33 23 22 43 24 23 30 26 24 30 27 25 28 28 26 32 29 27 34 30 28 35 31 29 40 Apr. 1 30 33 2 July 1 34 3 3 34 4 4 37 5 5 37 6 6 41 7 7 38 8 8 45 10 9 39 11 10 40 12 11 33 13 12 39 14 13. 38 15 14 38 16 15 34 17 16 39 18 17 41 19 18 62 20 19 41 22 21 71 23 22 71 24 23 40 25 24 .... 41 26 25 48 27 26 40 28 27 38 29 28 39 30 29 63 May 1 30 40 2 31 40 3 Aug. 1 37 5 2 40 6 3 40 7 4 40 8 5 . . .. 41 9 32 33 33 39 31 32 6 40 10 7 40 11 8 43 12 9 39 13 10 38 14 12 39 15 13 35 17 32 33 44 17 14 28 46 32 29 39 35 43 32 50 33 38 45 43 44 14 40 18 15 . .. 39 19 16 43 20 10 9 9 17 18 10 10 15 15 15 15 15 15 16 ]5 17 17. . 40 21 18 40 22 19 37 23 21 39 24 22 39 25 23 38 26 24 44 27 25 41 28 26 37 29 27 40 30 28 29 . . .. 41 31 24 June 1 31 40 3 Sept. 1 34 4 2 35 5 3 45 a Abnormal; probably present as HCO3 at time of collection of samples. WYNOOCHEE RIVEE. 51 Color and alkalinity of the water of Chehalis River at Centralia — Continued. Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3) Bicarbon- ate radicle (HCO3) 1910. Sept. 4 16 16 14 16 8 16 14 8 8 8 16 8 8 8 8 8 16 16 16 16 16 16 15 10 16 76 78 36 24 24 24 24 24 22 22 10 16 20 22 22 22 20 16 20 20 16 16 16 24 22 24 250 108 436 86 78 60 62 0.0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 «3.6 .0 04.8 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 37 39 40 39 39 26 40 46 48 43 43 46 43 46 43 43 41 37 37 41 38 43 40 37 23 33 28 23 16 24 15 28 27 26 34 39 52 45 28 28 22 33 29 33 30 33 33 38 35 31 28 18 22 16 17 16 20 18 1910. Nov. 15 32 32 58 164 40 30 36 40 78 78 78 32 32 18 16 14 15 16 14 16 28 38 16 15 13 - 34 98 62 40 40 42 19 54 50 32 .34 32 32 20 16 16 24 40 36 16 18 18 12 48 0.0 .0 .0 .0 .0 .0 .0 :S .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 a A .05 a .05 a .05 .0 a .1 23 5 16 23 6 20 19 7 21 15 8 27 22 9 29 21 10 30 22 11 Dec. 1 18 12 5 30 13 6 29 14 7 . . 17 15 8 ... 22 16 9 . ... 9.8 17 10 24 18 11 24 19 12 26 22 13 24 23 14 ... 21 24 15 . . .. 22 25 16 28 26 17 24 28 19 26 30 20 24 Oct. 1 21 26 3 22 24 4 23 24 5 24 17 6 25 17 7 26 22 9 27 22 10 28 18 11 29 22 12 30 21 13 1911. Jan. 1 14 15 20 17 2 17 18 3 22 20 4 24 21 . 5 23 22 6 24 23 7 24 24 8 25 26 9 23 27 10 22 28 12 21 Nov. 2 13 22 3 14 27 4 15 22 5 16 23 6 17 18 8 18 17 9 19 110 32 32 30 36 13 10 23. 18 11 24 19 12 25 23 13 26 18 14 a Abnormal; probably present as HCO3 at time of collection of samples. WYNOOCHEE RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Wynoochee River rises on the slopes of Mount Churtan, in the Olympic Mountains, and flows southward into Chehahs River below Montesano. The upper part of its basin is heavily timbered and receives an annual precipitation of 100 inches or more, much of it 52 QUALITY OF SURFACE WATERS OF WASHINGTON. occurring as snow. Except at the extreme headwaters of the river the exposed geologic formations are of Upper Cretaceous age.^ Wynoochee Eiver is locally important because of its proposed use as a source of supply for Aberdeen, to which water is to be carried by gravity from a point near that at which samples were collected. Almost the only habitations in the basin are temporary lumber camps. CHARACTER OF THE WATER. Samples of water from Wynoochee River at Frye's logging camp, 20 miles above Montesano, were collected from July 17 to August 19, 1910, inclusive, after which period it was impossible to obtain samples. As the river was low during the samphng period the analyses probably indicate more highly mineraUzed water than a year's average would have shown. The water is soft and excellent for municipal and boiler use. No treatment is necessary before using the water for industrial purposes. The river should provide a satisfactory supply for Aberdeen if its volume can be made suflB.cient at all times by storage and its basin kept free from lumberers and trespassers. The principal dissolved materials in the water are siHca, calcium, and bicarbonates. It was thought that large amounts of cycHc chlorine would character- ize the water of this river, but the average content, 2.1 parts per million, is not so large as that of waters draining the humid regions of the Coast Range in Oregon, which are comparable in rainfall with the Olympic Mountains. This surprising fact is not yet adequately explained. Mineral analyses of water from Wynoochee River near Montesano, 1910. [Parts per miUion unless otherwise stated.] Date. '2 p ©^ o +f Kl © .2 i=l S 2 e5 ©^ o o O i fa g 1— ( '5' o a o a © tx; Sodium and pot a s s i u m (Na+K). 1^ 6 ©^ t, © ©o 03 ^^ SZ © CQ .2 © .a a 1. From— To— 73 > .a July 17 21 31 July 20 30 Aug. 9 19 an »e of anhyc 1 1 1 5 1.0 1.3 1.00 1.30 11 16 11 5.8 0.02 .02 .01 Tr. 8.6 8.4 8.1 7.7 2.4 2.1 2.2 2.2 5.8 4.7 3.6 5.2 0.0 .0 .0 .0 37 39 34 33 9.7 "3.'7* 3.6 0.50 Tr. Tr. .65 2.0 1.9 2.0 2.4 55 59 50 Aug. 10 2.4 .48 47 Me Percenta 2 JOUS 1.6 residu .93 e 11 21.2 .01 .0 8.2 15.8 2.2 4.2 4.8 9.2 .0 34.0 36 5.7 11.0 .29 .6 2.1 4.0 53 COLUMBIA RIVER BASIN. GENERAL FEATURES. The drainage basin of Columbia River comprises about 259,000 square miles in northwestern United States and southwestern Canada. Its eastern border is the crest of the Rocky Moimtains and its north- 1 Willis, Bailey, Index to the stratigraphy of North America: XJ. S. Geol. Survey Prof. Paper 71, pp. 572, 778, PI. I, 1912. COLUMBIA EIVEE BASIN. 53 western limit is among the peaks of the Cascades; its lower portion receives drainage from the Coast ranges. The basui is divided among several States and British Columbia as follows : ^ Square miles. Nevada 5,280 Wyoming 5, 270 British Columbia 38, 700 Square miles. Oregon 55,370 Washington 48, 000 Idaho 81, 380 Montana 25, 000 Columbia River, the trunk stream of the system, rises in Columbia Lake in the eastern part of the Kootenai district of British Columbia. It flows northwestward to the fifty-second parallel, turns abruptly southward, nearly paralleling its former course, passing through a series of narrow lakes until it crosses into Washington near the Idaho line. After a sUght westerly deflection it then resumes its progress southward to the Oregon- Washington fine at the forty-sixth parallel, where it swings west, and finally discharges through an estuary into the Pacific Ocean. It is navigable in places for 760 miles, and 2,136 miles in the entire system are navigable. The important tributaries of Columbia River are listed below: Principal tributaries of Columbia River. Entering from north and west: Kettle River. Sanpoil River. Okanogan River.^ Methow River. Chelan River. Entiat River. Wenatchee River.^ Yakima River. ^ Klickitat River. ^ White Salmon River. Lewis River. Kalama River. Cowlitz River. Entering from south and east: Kootenai River. Clark Fork. Colville River. Spokane River. ^ Snake River. ^ Walla Walla River. Umatilla River. ^ Willow Creek. John Day River. ^ Deschutes River.^ Hood River. Willamette River.^ Clatskanie River. The drainage basin of this system includes all varieties of topog- raphy from the bold peaks of the Cascade Range and the west slopes of the Rocky Mountains to the flat, sandy plains of the ''Big Bend country," lying east of the river between the mouth of the Spokane and that of the Snake. Much of the area is forested, and although extensive lumbering has been carried on the proportion of forest lands has been only sHghtly decreased. Precipitation is unevenly distributed as to both time and place. Summer rainfall is small, in most of the region. In some places, as along the coastal strip and at the summits of the Cascade Range, the 1 U. S. Geol. Survey Water-Supply Paper 272, p. 64, 1911. * Studied in connection with investigations in Washington. > Studied in conoiectioii with investigations in Oregon. 54 QUALITY OF SUEFACE WATEKS OF WASHINGTON. average annual precipitation is 100 inches or more, but it decreases rapidly eastward from the peaks of the mountains^ and in the arid lands of eastern Oregon and the low valley of central Washington it is 9 inches or less. In the coastal belt the climate is mild, the sum- mers being cool and the winters warm. In the vaUeys between the Coast and the Cascade ranges the cHmate is still mild but is less even. In the high plateaus of the interior high summer and low winter tem- peratures prevail, and on the elevated headwater regions the climate is extremely rigorous. It has been estimated that at least one-third of the available water power of the United States is afforded by the streams of this drainage basin, but only a small part, probably less than 200,000 horsepower, has yet been developed, though several large power projects now planned or under construction will materially iacrease this amount. Many sites along Columbia River itself are capable of developing as" much power as is now used in Oregon. The utiUza- tion of some of these sites, located on lines of both water and rail transportation and in regions of favorable climate, will do much for the industrial development and prosperity of the Northwest. The only generally important industries of the region are lumbering and agriculture. Some mining is carried on in the mountains, especially in the Rockies. Ancient strata, largely metamorphic and ranging from Proterozoic quartzites to Jurassic and Triassic or even younger sediments," are exposed at the heads of the tributaries rising in the Rocky Mountains, Mesozoic intrusives cover large areas in Idaho and southern British Columbia, and pre-Cambrian gneisses occur in parts of Idaho; but the greater part of the basin, including most of the valleys of Snake and Columbia rivers iu the United States, is covered by thick sheets of basalt of Tertiary age. The soil of the basin in Washington is generally rich and fertile, but that covering much of the basaltic plateau is '^ volcanic ash," or pumiceous sand and disintegrated basalts, and it lacks humus and is poor in phosphorus. SPOKANE RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Spokane River rises in Coeur d'Alene Lake, in western Idaho, flows generally westward and northwestward and joins Columbia River at Fort Spokane, Wash., just above the ^'Big Bend." From Coeur d'Alene Lake to the city of Spokane the river flows through a broad, shallow vaUey, but below that city it enters the narrow, gradually deepening canyon which characterizes its lower course. Granitic rocks predominate in the mountainous wooded region around its headwaters. The lower river traverses the prairies of COLUMBIA EIVEE BASIN". 55 eastern Washington, where the underlying formations are Tertiary basalts and tuffs. A ledge of basalt blocks the channel of the river at Spokane and produces Spokane Falls, from which 12,000 horse- power is developed. Other plants along the river produce an addi- tional 45,000 horsepower. The mean annual precipitation is 17 inches at Spokane and is prob- ably less than 20 inches throughout the drainage area. The prairies are suitable for raising grain, and the valley lands support productive fruit orchards. The soils are rich and fertile, the generally slight rainfall being insufficient to cause too great leaching of lime and potash from them. Though the upper valley of tbe Spokane is well populated, few people dwell along the lower river. Spokane, with a population of 104,402^ in 1910, is the largest city in Washington east of the Cascade Mountains and the second city insize in the State. Its principal indus- trial establishments are lumber mills, flour mills, and machiae shops. It is the chief distributing center for what is known locally as the ''inland empire" and it has exceptional railroad facilities. Its water supply, which is obtained from wells driven in the sands of the river bed, is considered satisfactory for ordiaary purposes, although the water is very hard. CHARACTER OF THE WATER. Samples of water from Spokane River about 8 miles above the falls were collected under the direction of the city health officer from January 1 to June 1, 1910, but thereafter, until January 31, 1911, owiag to the difficulty and resulting irregularity of collection, the samples were taken in the city at the gaging station of the United States Geological Survey by the gage reader, A. C. Lingle. The drainage area above the gaging station is 4,000 square miles. The river furnishes a calcium-carbonate water, low in mineral matter and excellent for all ordiaary industrial uses. Ordinarily it will probably not corrode boilers, but it is likely to be actively corro- sive when organic matter is high. Corrosive action at such times could, however, doubtless be prevented by leaving in boilers a thui coating of the medium hard scale that w^ould be deposited. Though the water is subject to considerable variation in amount and char- acter of incrusting material, the content is always too small to make chemical treatment necessary or advisable before boiler use. If the river water were properly filtered or otherwise purified, it would make a most acceptable supply for the city and would save the community large sums each year by decreased soap consumption alone. 1 Thirteenth Census of the United States, 1910. 56 QUALITY OF SUEFACE WATERS OF WASHINGTON. !3 S ■♦^ W ^ 1-iooooooorooor^cciM OS CO -^ c^i eo T-H •2 ^- "50000C0C00 «5t-^O>S<00-H0C0CC5C0Cr-( l^l>.C5»OC5r- IOIOCOC5 05'-!i-OCOCOiOOOOOOOe<5COCOOOC-i-v(N»ococot^c^oc i^O"— iC^O'^'-i'— ii-<0503'-"— ii— iC^- "2 fioo O «3^ r}.oofo05^J^oo»o»OlC»o^ofo^-<■^•o^^ ooooooooo-*o OOOUSO^O^i „ ^ „ „ OOOOOC;00^-} cdox'-q^iccO'C'd'-ioi'— ioo5coo6'^oit»o6ooio6i-<'-i OS ■^ O 01 g 2 03 © . ij c3 ^ ^ X2 fc.'^-' «ooooooo t^oi OOO OO O OO O O O O OOO O OOOOOOO O O !0 osi-H eo •<»' i o a5(M t^ ■v" 00 OS • ■«< ■^ U3 cci>.ot>'t>-ot^'<»<-«"C^oiMos'-io5050C^oooo5»c>oe^ »/sec»d'^io«didoio«5t^"5!6>o«D'^e<5coe4cc'9''j!50co e«5(N •006 o <— I •* r^ OS 00 N 00 (m" »-! —i T-H OOSC^ X O C<1 OC.Tf oc o ■«ti 00 OS OC IM U5 »C P3 CO CS|OOO0(N o oos^ t^t^coeooos'-icocdeo«0'-io6i-Hi-ioso6osi-ii CO e O l-H --H. o ■ i-l C<1 <-! CC^ -1-3 P.9 CJ -^ 1^5 Tt< ■«• t^^ (M (M C0-«»>00'<»<(MI~-(NCO->J-t^t^t~»cDCOcO'-J 1-1 -H e> ^^ O ^ u wM SO t-c J? T) From— To— 2 3 3 i a o a o (A c3 '-'2, 3 2 5 CD t-, « a^ C/3 C3 C OT •Eaa OX) ^-T^ O c3 O c6 t^OOCMOSt^.— (COiOC^iOOOtO-— l03t^CO;00(MOO-H a> ' C0»0 CO IN 0) Co CO tj O -i-^ '^ O CO COIN'— lc000t^030>t^00OOCD-J<— <00TfOi0CD000iO-^0005INt^>— iiot^-^coocDOsoscoioror^coioioioco-^coiot^ Tf00'»9iCClCO(NO r-T i-T rH (n" io~ irT cc "o^ co~ l^^ c^^ -^ 00 ocT »o^ ccT U5~ CO of i-T T-T CS CO IN IN CO lO IN I i-ii-ii-(C ^ O lO >0 • 00 CO tH -H O CO .— I — I 00 ^*< lO • CO lO t^ r^ 1>- CO t^ 0 — < CD O 0> ■-< rf< -"J" CO 'S' i^t>-oo •locO'-no-^'^-^'oeoco-^ •eocococo-^-^->a''a'cocoeocococo-'*o lO 1-1 (N 10 O CO • (N CO t-^ t^ 00 00 ■qicoiot^"^i3^t-cocoioot--^Ht^o6iococoio»oo6'^t~~ioiOi CO 1— I 1— ( on t^ lO I 05 CO CO ^ uj 10 CO T-Ht^Tf(NC0C0iNC0C0^HINTf<01c0OO03t^0000cO»-i0000.-i01 rHCO>000 iNCaiN 1-1 IN 1-1 IN (N 'l>-rHCOOOO'«*0'^COCOCOiQiOin'0'^'*»0'^U5iO'Oid>OiO ■ XI' ^1 .— . -, .-, „; -s -J 1—1 CO 1—1 O) -,,• ^H »— 1 1— I ^; c<) T— I c0 OJ 1— I Ol O Tfi CO COOi-OCOi-llOlNrH iO»O»OCD'»iQ'Hr-i— (O-^OOO coco ' 1-H eS 'coco 'i-5i-Hc6i-5 * 'i-Hi-JrHi-H LOOOOOOOOOiOOOOOOOOOOINOOl^i-lt--COTHlOTtO^C^INiOiNi-lT-li COi— IIN -^1— 11— IIN 1—1 1— 11— ( 1—1 OOlNININi l,_l,_l,_l,_lOOOOOOl35C»OiOOOOOOOOOOOOI>t^£-l>l>t>-COCOCOi-l I I-l IN CO 1-1 Oq 00 r-( IN CO 1-1 > cS s CuO 2 O ^ M K. pj ea i-iT-H.HeococoiNesi(NiNiNiNrHi-i;Hi-ii-i--HrH000050>^050i^oooooooooo«t-r^t- ^+j ,-(01 1-llN I-l (N 1-1 IN r-iiN I-l Ol C0 1-1 O* eo THIN iH IN i-i Cq 1-1 IN i-i IN r«=i fl Ph ^ >> ft 03 -^ ;^ <1 PH W COLUMBIA RIVER BASIN. 63 Color and alkalinity of the water of Wenatchee River at Cashmere. [Parts per million.] Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. jfar 11 14 16 16 16 18 16 16 12 16 18 18 12 8 8 6 Trace. 4 2 10 28 16 8 8 8 6 8 8 10 8 8 12 12 12 20 14 6 " 8 8 7 0.0 .0 .0 .0 .0 .0 olO .0 .0 .0 .0 .0 .0 .0 .0 o2. 4 a 2. 6 .0 19,1 04.8 0I2 04.3 a 6. 7 all .0 a 1.4 a 10 .0 .0 all .0 a5.8 .0 a 12 .0 04.8 al3 ol3 0I2 50 48 51 53 48 47 42 45 40 38 35 38 40 33 49 40 39 41 36 40 25 34 31 34 39 22 8.5 31 42 12 22 6.8 25 12 13 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 Apr. 1 3 5 20 22 24 25 26 27 28 29 . May 1 29 16 2.9 3 4 5 Date. May 6. 1910. June 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 9. 10. 11. 12. 13. 14. 15. Carbon- Bicarbon- Color. ate radicle ate radicle (CO3). (HCO3). 7 a 13 6.3 8 .0 25 16 14 09.6 oil 2.4 8 04.8 10 7 032 6 .0 20 8 .0 16 8 .0 21 6 .0 19 6 .0 19 6 ol4 5.4 5 04.8 11 8 .0 21 8 01.2 31 8 .0 26 8 .0 15 10 .0 24 8 .0 17 6 .0 19 8 a 6. 7 9.0 4 .0 18 .0 .0 20 6 15 8 a 9.1 16 6 .0 20 6 .0 20 4 .0 20 6 .0 16 6 .0 15 8 .0 19 8 .0 18 4 .0 20 4 .0 16 6 .0 15 6 .0 22 10 .0 17 8 .0 19 8 .0 16 a Abnormal; probably present as HCO3 in water at time of collection. YAKIMA RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Yakima Eiver heads in Keechelus Lake 2,458 feet above sea level, near Snoqualmie and Yakima passes in the Cascade Moimtains. It flows in general southeastward about 150 miles, and discharges into the Columbia a few miles above the town of Kennewick. The upper river flows through heavily forested, mountainous country, about 5,500 feet above sea level. Precipitation is abimdant, averaging 26 inches at Clealum and increasing rapidly to over 60 inches a year at Keechelus Lake. As the greater part of the precipitation occurs in fall and winter, much of it as snow, and as midsummer precipitation is almost nothing, there are annually two periods of low water and two periods of high water. Low water occurs usually during the midwinter months, while snow is accumulating. Spring thaws cause high water, which generally reaches a maximum late in the spring and gives way to the low-water stage of summer. Rains late in the 33476°— wsp 339—14 5 64 QUALITY OF SURFACE WATERS OF WASHINGTOIT. autumn bring a second, less pronounced high-water stage, which in turn gives place to the low water of winter. In its middle and lower courses the river flows through a series of wide, fertile valleys that extend to the plains of the Columbia. Rain- fall is deficient, ranging from 10 inches at Ellensburg to 6 inches at Kennewick, and this part of the drainage area is practically unforested, except among the mountains that form the western wall of the val- ley and among the Wenatchee Mountains on the north. Naches River, Tieton River, Cowiche Creek, and Atanum Creek flow from the west to join the middle Yakima. Toppenish and Satus creeks drain the southern highlands, and several small streams, entering from the north near and above EUensburg, head in the Wenatchee Mountains and form the only important tributaries from the north and east sections of the drainage area. The lower Yakima is in a semiarid country and has no tributaries. The upper Yakima River valley exposes pre-Eocene schists, slates, serpentines, and volcanic rocks, Eocene sandstones, conglomerates, shales, and basalts, and in places Mocene and later basalts. Above EUensburg the river crosses an exposure of Miocene basalt and enters the later Tertiary sedimentary deposits known as the Ellensburg formation, and in its lower course flows across basalt and sandstone. N ACHES RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Naches River, a tributary of Yakima River, rises in the Cascade Mountains, in the western part of Kittitas County, and flows south- eastward, discharging into Yakima River a short distance above North Yakima. Its total length is about 50 miles, but its head- waters drain a stretch of the Cascade Mountains 50 miles in extent. Precipitation is abundant around its headwaters, and although its vaUey lands are semiarid its annual discharge is equivalent to a depth of about 20 inches on its drainage area. A large part of the basin is forested with yeUow pine, red and yeUow fir, tamarack, and some hemlock and other conifers. The geologic formations exposed near the source of the river include large areas of Tertiary sandstones and lavas, together with some more recent andesite. CHARACTER OF THE WATER. Samples of water were coUected daily from Naches River below the entrance of Tieton River at the power house near the town of Naches from February 1 to June 30, 1910, when the station was discontinued. A gaging station is maintained by the United States Geological Survey 5 miles above Naches and below the mouth of Tieton River. The drainage basin above it comprises 930 square miles. COLUMBIA RIVER BASIN. 65 The water has a slight amount of temporary hardness but is not usually concentrated enough to render treatment for boiler use necessary. It is a calcium-carbonate water with minor proportions of alkalies and sulphates. As the samples were collected during spriQg freshets, the amount of suspended matter is probably much greater and the amount of dissolved matter probably less than they would have been throughout the year. The water is well suited for irrigation, the chief use to which it is to be put. It wiU become more unsafe as a source of municipal supply as the population of the drainage basin increases, and it now furnishes an undesirable supply to North Yakima. The water is treated by adding to it sodium hypochlorite in the proportion of 8 or 10 pounds of the reagent to 1,000,000 gallons of water, but the city health officer states in a personal communication that the treatment is not always effective and that it is evidently unskiUfuUy performed. The determinations of the color and alkaHnity of water from Naches River, made daily from March 3 to June 26, 1910, show a gradual but irregular decrease in both qualities, but the variations bear no apparent relation to rainfall. Probably melting snow on the Cascades has the most pronounced influence, for the snow melted more and more rapidly as the season advanced, and alkaHnity and color show a more or less regularly increasing dilution. The color in early spring was high and caused considerable complaint among those who used the supply for drinking. Coagulation and rapid sand fil- tration followed by properly supervised addition of hypochlorite would decolorize the water and render it safe and satisfactory for municipal use. Mineral analyses of water from Naches River at Naches, 1910. [Parts per minion unless otherwise stated.] Date. 6 ^X r2 -S .2 m m El CQ CQ t-i 1^ CQ K 02 s u Feb. 1 Feb. 10 5 3 0.60 26 0.10 8.8 2.4 7.4 0.0 45 8.6 0.22 0.4 80 11 20 5 4.8 .96 31 .13 10 2.4 7.2 .0 52 8.9 .50 .6 89 21 Mar. 2 100 84 .84 25 .20 9.4 a2.5 8.5 .0 47 12 Trace. .7 82 Mar. 3 12 20 32 1.60 24 .15 8.8 3.1 5.7 ?)4.3 37 8.9 Trace. .4 74 13 22 30 73 2.45 20 .25 8.1 2.7 6.8 bll 22 8.1 Trace. .4 74 23 Apr. 1 40 37 .92 20 .02 9.5 3.1 7.7 .0 48 3.5 .20 .2 67 Apr. 2 11 25 19 .76 26 .08 9.6 3.2 6.9 .0 48 5.8 .00 .4 76 12 21 60 61 1.02 17 .05 8.4 3.1 7.0 .0 52 3.1 Trace. .5 66 22 May 1 28 34 1.21 30 .01 7.5 2.2 5.5 .0 44 6.3 Trace. .5 79 May 2 11 21 "25" a 30 26 12 1.04 ! 32 .02 6.7 2.4 6.3 .0 39 2.6 .00 .3 76 22 31 15 17 1.13 18 .01 6.5 2.0 4.5 .0 34 2.5 .00 .3 52 June 1 June 10 10 6.8 .68 1 16 .01 6.7 1.9 2.4 .0 31 3.9 .3 59 u an... 20 30 10 21 6.0 1.4 .60 i 16 . 70 1 22 .01 .01 5.8 4.3 .0 .0 29 37 .3 .3 61 21 6.8 2.2 2.8 .00 65 Me 27 29 1.04 1 23 .08 8.2 2.5 6.1 .0 43 5.9 .08 .4 71 Percenta ge of i iiihy drouj 3 residue } 34.1 C.2 12.2 3.7 9.0 31.4 8.7 .1 .6 ff Estimatecl , h Aboormal; computed to HCOg in average. : FejOi. 66 QUALITY OF SURFACE WATERS OF WASHINGTON. Color and alkalinity of the water of Naches River at Naches. Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar.3 65 30 54 58 0.0 0.7 .0 o2.4 38 46 49 44 40 45 44 52 38 40 38 44 45 45 40 40 40 41 43 41 41 46 41 46 1910. Apr. 8 8 8 8 8 10 9 10 8 8 8 8 8 10 18 16 16 14 8 8 7 8 8 8 0.0 a 9. 6 a 19. 2 a 16. 8 a 21. 6 a 38.0 14.4 .0 .0 0I2.O 0I2.O a 12.0 .0 a 7. 2 .0 .0 .0 .0 .0 04.8 a 4. 8 .0 a 6.0 44 4 9 . 27 13 10 .. 4 Q 14 22 6 1 15 26 .. . . n 16 52 24 56 78 36 16 16 20 8 8 8 12 2 6 .0 .0 Trace. .0 Trace. .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 04.8 .0 29 17 30 li 18 May 16 34 20 17 33 22 18 6 1 23 19 18 24 20 11 25 21 30 27 24 26 28 25 30 29 26 27 30 27 55 Apr.l 29 37 2 30 37 3 June 22 32 4 8 23 28 5 25 40 6 8 8 26 24 7 a Abnormal; probably present as HCO3 in sample as collected. YAKIMA RIVER AT CLEALUM. GENERAL FEATURES. Clealum is situated on Yakima Eiver 6 miles above the mouth of Teanaway Kiver and 3 miles below the mouth of Clealum Eiver, at an elevation of 1,908 feet above sea level. The surrounding country is rough and mountainous and contains several important coal de- posits. The winter cHmate is severe but changeable. The annual precipitation, mostly snow, is about 26 inches. Floods occur in Yakima River late in the fall or early in the winter and late in the spring; the spring freshets are usually though not always the greater. Yakima Eiver at Clealum carries the waters of Keechelus, Kachess, and Clealum lakes, and its water is therefore representative of all the principal headwaters of the river. Storage in the lakes regulates the discharge of the river so that it is not so ''flashy" as it otherwise might be. CHARACTER OF THE WATER. Samples of water were collected by S. A. Mortland from the river near the left bank about 100 yards below the bridge near Clealum. A gaging station is maintained at the highway bridge just above Clealum; the drainage area above that point is 500 square miles. The water is soft and free from large amounts of either suspended or dissolved material. As it usually contains much organic matter, probably of vegetable origin, it may at times cause corrosion in boilers, but gives little trouble from scale and needs no corrective COLUMBIA EIVER BASIN. 67 treatment for boiler use. Slow sand filtration would probably be sufficient to render it suitable for domestic use. The water is characterized by shght secondaiy salinity, which in- dicates that the predominating rock formations are sedimentary. Though andesiteS; basalts, and rhyoUtes, with some older schists and slates, predominate at the headwaters of this stream, they are suc- ceeded by Tertiary sandstones, shales, and basalt. The Tertiary materials are the most readily soluble and probably give the water its distinguishing characteristics. Both color and alkalinity are low, as shown by the accompanying table. The alkalinity decreased slightly because of dilution by rain and melted snow. 68 QUALITY OF SURFACE WATERS OF WASHINGTON. s ^ w >> -- IM 05 05 M fi' ro <» Kl o C ^ OOCOOOfOOOce500c«5T}<00«OOOOiOOO'-HC<5000t^-a-icoO'oa5-^iMt^oo»ooo-^ioiM»oeo. ^-('-IC^C^OOCO'-^I-ll-^^— li-lr--ICSlt5C<>l--li-l iO:0-Ht^Tt"TfiO00OC0Ot^»-i-^iCO-^C0t^OT»<0i __. ,__. ___lOrCI:^0-*COOOfO»0CCi-IXt^«OiCOC0CD-HOO30O l-( .-I rH C<1 «0 -^ (N TT t-- to lO -V C^ (M »-< i-H i-H »-H i-H 1— (tH>— II— ICQ'^C^i— CI— 11— itH ^ TO' c^c^c- iO to • Tf< iO lO O »0 CO ■V ■* «3 t^ -V -^ "3 »0 -^ ■^ -V -^ to CO -"ti -* rji ■<»< CO CO T CO "^ CO •>»' ■* -^ •<»< rr a: M ICO o XlOOO»OiO'Ol^'*l>-C^'HOOtOOC005C^05t>-t^i-(COi-l(N»-ICOt^!NOOO'<*.-<*i'^ 'i-i ' ' T-5 c-! i-i »-^ i-5 * rn i-i t-5 »-h i-i to -^ i-< CO Z26 OiOOOO o to »o o »o oco»ooc5®4'ffiffl®®®®®c) 1-1 i--\ f^ f> /*> .-^ f-\ /•\ f\ c> ^1 CT CI .-> "-^ ^ ■* •* **^ ^ ■■ ^ l-^ ^> ^> "^ **^ r-\ /-> o g Ui b> (h (h ' ^ E-i E-i £- E-i i (NO i-ITti-^t-T-*tOOtOCcO'otoe^t^oo»o»-i'Ti<'^i>»ci3x)iTj5Ti0'^e<3C^««5'*»oc0 CO . to kO O tocooo OOf to o ocor^oo to 00 r- -^ iM oo ^c4 »-l H Eh &H Eh o « O; C^ X t^ O C O X -^ CTil:^ to X ^^ t^OO »o-^iO S c '=1 » -2 Eh o c^ uj X f-^ CO >-5 C<1 1-1 1-1 1-1 1 COOtJi COCO * i-J OC^i-Hj-lClrHTHeO to S) i-lT-(i-l rHi-ICSli-l ,_Hgi-l 1-t I-I OS lOOOOOO0505CiXXX00XXt>-l>.t^l>t^l>-Ot0t0i-l »-< o< ec i-i cvi CO »-i cq CO i-tcvi thc^ i-icq ft <5 03 ^ ft <5 s 3 bo ft 1-s COLUMBIA RIVER BASIN. Color and alkalinity of the water of Yakima River at Clealum. [Parts per million.] 69 Date. Color. Cafbon- ate radicle (CO3). Bicarbon- ; ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. jfar 14 4 Trace. 4 4 3 3 Trace. 2 2 Trace. 2 2 2 2 Trace. Trace. 3 4 2 2 2 8 8 0.0 .0 .0 .0 .0 .0 a 2. 9 .0 .0 .0 .0 .0 .0 .0 .0 a 2. 4 .0 .0 .0 .0 O29.0 a 5. 3 a 12.0 .0 04.8 a 26.0 a 14. 9 a 16. 3 020.4 .0 0I9.7 a 12.0 "5.8 34 33 31 34 30 29 32 31 36 35 39 35 33 33 33 33 33 28 31 30 44 22 12 33 27 1910. May 5 2 4 12 8 4 8 6 0.0 a 10. 8 .0 .0 .0 a 8. 4 .0 .0 .0 .0 .0 .0 07.2 .0 a 15. 6 .0 .0 .0 .0 .0 a 4. 8 "3.4 .0 .0 .0 .0 .0 a 3. 6 ,0 .0 .0 .0 .0 28 16 6 10 18 8 30 20 9 29 22 . . 10 27 23 11 12 26 12 27 27 13 34 28 14 24 29 15 20 30 16 28 Apr. 1 17 28 2 18 8 27 3 19 32 4 . . 21 4 4 13 5 23 27 6 25 24 7 26 30 8 27 29 9 28 26 12 29 33 13 30 33 14 31 4 32 15 June 1 30 16 2 27 17 3 30 18 12 4.1 24 30 4 2 8 27 19 5 28 22 6 17 23 7 25 24 . . 8 29 25 7.3 16 9 27 26 10 28 a Abnormal; probably present as HCO3 at time of collection. YAKIMA RIVER AT PROSSER. GENERAL FEATURES. Prosser is situated in western Benton County in a rich agricultural section of lower Yakima Valley, which, includes the Sunnyside project of the United States Reclamation Service. This arid valley is fertile where water is applied to well-drained tracts, but poorly drained places are "spotted'' by black alkali. The soil is rich and contains much potash and phosphate, and it is rendered very productive by irrigation. Series of Tertiary lake sedi- ments and vast stretches of Yakima basalt are exposed in the basin. Most of the tributaries of Yakima River below Clealum flow from a region of basaltic and tuffaceous effusives. CHARACTER OF THE WATER. Samples of water from Yakima River at Prosser were collected at the flouring mill by Albert Smith from January 21 to June 20 and by Dr. D. M. Angus, county health officer, from August 20, 1910, to January 31, 1911. The amount of material carried in suspension and in solution between June 20 and August 20, 1910, has been esti- 70 QUALITY OF SURFACE WATEBS OF WASHINGTON. mated by interpolation in order to complete the yearly estimates of denudation. A gaging station is maintained at Kiona, 14 miles below Prosser. The drainage area at Kiona is 5,230 square miles and at Prosser is 5,050 square miles. The estimates of discharge entered in the table of analyses have been corrected for the difference in size of the basin. The water is characterized by temporary hardness and can be softened for boiler use by adding small amounts of lime or by pre- heating in open heaters; it will probably cause no trouble by corro- sion or foaming, though it contains much organic matter and is badly polluted by sewage. The writer has seen soHd particles of sewage in the river above the outlets of the sewers at Prosser. North Yakima, notwithstanding prohibi'^ive legislation, was discharging its untreated sewage into Yakima River in 1910, and this sewage un- doubtedly passed Prosser less than one day later. Investigation^ has recently demonstrated that much of the typhoid fever in this district is due to contaminated water supphes, and it is evident that the water of Yakima River is being grossly polluted with sewage and is entirely unfit for domestic use in its present state. Daily determinations of the color and alkahnity of the water of Yakima River at Prosser were made from March 13 to January 24, 1911. Color was strong during the spring but decreased gradually until midwinter when the water was nearly colorless. As the water of Yakima River at Clealum and that of Naches River are both less highly colored than that of the Yakima at Prosser the latter probably obtains much of its color from tributaries other than the headwaters. The streams flowing from the Tertiary lake beds comprising the EUensburg formation possibly contribute some color. Sudden great increases of color accompanied general rainstorms— as, for example, early in April. The alkahnity of the water decreased during spring and increased during summer, so far as the incomplete records of conditions in summer indicate, and decreased again during winter. Alkalinity, therefore, varied inversely with stream flow. Coagulation and rapid sand filtration would be the most satis- factory treatment for this water, if it were used as a municipal supply. 1 Lumsden, L. L., The causation and prevention of typhoid fever with special reference to conditions observed in Yakima County, Wash.: U. S. Pub. Health Service Pub. Health Bull. 51, 1912. COLUMBIA EIVEE BASIN. 71 t-i bill's i<-*u3t>.ioi— e-iO'*c«e^csciccio«Dt>-T-i?ocoooot--.t>-«Dt>. 50i-itOt>- ■^ o Oi CO»-H 00C5 O "C ■ C ci3 C c3 t^COlOlClCI>'tOO-^50'^CX)t>-CO>-lt~(N-^0->*"i-IC^OOeO>005'-l500<-<'0050>0«303C» CO O lO (N 05 «0 lO (N C^ t^ O t— (N lO 00 -^ CO -H _ r-l i-l tH i-l CO CO 't* CO (N CS C^l c5ecoa>cxi(Nr-t____'"„ c^ic^i" .O lO -o .o « I- 1^ 5 O O QJ o HOOOCOOS--ir^lO^HiCCO"5'^-«ticO-^05'005-rcic-eoo>o»ooiO'^»oc<«coooo5 ooooiocO'-Hioicxoocooc c^Tt<«5cocot6o^'>rTt^t>^;deoood50 I eS T-( 1— I i-l tH rH 1-1 r-l '^Tt OOOOUSiCOOiOOO-^iOTjirH-*'*' '^eocoeoeoeoeo Tt-ie-i-i- C»»-i«5 0t>.cDt~»oeoccr>- ICOiOiOt-rrt^COiOO Oe<) rH rH rH T-1 rHrHrH OOsOrjio 0<000 OONOOOOOO OM(»otD■*N^p(NOeoe^^r^,HrHooooio5esode^^OldorH0005lO(^^r-^c^^r^'l-;rH e>J C^ r>- <-C eS rH e^ ;0 eS 1-1 C^ CO rH l-( rH 1-1 rH T-l 1-4 rH rH lO rH fO rO >0 lO .O rH 0) 3 3*2 >» ICOeSjeSrHOrHrHNC^rHCq ooioc^Tjtio'^useooco'^co'^cofoec rH rH rH rH i_| CO rH OOCOJp5WOOOOOOOOOQt>.r»t>.t»t^t^?0!OCOrH rHCq tHN rHM rH Cq CO rH CM CO rH Cq CO rH fj rH C^ rH C>4 rH C^ rH CSJ J-S ?q CO f^ 3 3 3 ft !::i S *^ £2 SS ^ £3 a ^ 2 S '^ ri S '^ n ;H rH o o o OS OJ oi OS OS o; 00 00 00 00 00 00 t^i^ t* rHN rHC^ rH (N rH N rH W rH N CO rH C> • 3 ; 03 -C3 6jC 1^1 72 QUALITY OF SURFACE WATERS OF WASHINGTON. Color and alkalinity of the water of Yakima River at Prosser. [Parts per million.] Date. Color. Carbon- ate radicle (CO3). 1 Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar. 13 208 90 62 62 65 60 86 86 38 36 58 32 78 208 168 172 54 20 16 80 78 32 24 36 16 8 0.0 .0 .0 .0 .0 .0 a 17. 3 a 7. 2 .0 .0 .0 a Trace. .0 .0 .0 .0 a6.0 .0 .0 .0 .0 .0 .0 ao.O a 15. 4 a20.4 a 14. 4 04.8 015.6 .0 .0 a 10. 8 .0 .0 .0 .0 .0 a 3. 6 .0 a 3. 6 .0 021.4 a 3. 6 a 9. 6 09.6 .0 13.2 .0 .0 .0 .0 08.4 08.4 2.4 .0 09.6 .0 .0 .0 07.2 .0 03.6 78 63 65 61 61 62 38 55 58 64 58 67 62 68 69 61 59 66 68 63 62 61 42 50 40 30 23 39 22 51 49 .2 45 56 54 56 47 51 38 39 44 14 46 37 30 51 26 50 48 72 57 40 39 57 63 30 48 55 52 38 55 43 1910. June 21 18 8 8 8 8 8 8 8 16 8 8 8 8 4 4 4 2 16 4 8 8 40 32 8 8 6 8 8 7 8 8 8 12 8 8 4 8 8 8 4 6 8 8 6 4 4 2 8 8 8 8 9 6 4 4 16 12 0.0 .0 .0 .0 :§ .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 :S .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 56 16 Sept. 23 164 17 24 171 18 26 172 19 Oct. 3 166 20 4 5 6 164 27 170 28 29 7 71 30 8 78 31 9 69 Apr 1 10 59 2 12 61 3 13 62 4 14 150 5 17 147 6 19 73 7 20 . -. 74 8 21 75 9 24 78 10 28 70 12 Nov 21 59 13 22 56 16 23 40 18 24 39 19 28 46 25 30 49 26 15 16 17 32 16 16 22 Dec 1 50 27 3 61 28 5 57 May 3 6 . . .. 61 4 7 63 5 8 61 6 9 66 8 11 62 10 24 19 16 16 48 42 22 16 16 78 30 16 16 17 78 32 16 24 90 58 32 90 54 90 78 24 98 12 63 11 13 63 12 14 67 13 16 66 20 17 63 21 19 67 23 1 20 67 24 22 68 25 25... 78 30 26 76 31 27 76 June 1 1911. Jan 4 2 3 71 6 5 78 7 6 76 8 7 76 9 8 73 11 9 74 13 10 74 14 11 . : 77 15 12 74 16 13 71 17 17 74 18 21 72 19 23 73 20 24 68 o Abnormal; probably present as HCO3 when sample was collected. SNAKE RIVER. GENERAL FEATURES OF DRAINAGE BASIN. Snake River flows from its source in Yellowstone National Park across Idaho, then northward between that State and Oregon and Washington through a steep canyon to Lewiston, Idaho, where it is COLUMBIA EIVirR BASIN. Y3 joined by the Clearwater; it there turns sharply and flows westward through Washington to its confluence with the Columbia below Pasco. The river drains an area of 109,000 square miles. The river crosses the Columbia River basalt and throughout its entire lower course occupies a steep- walled canyon about 2,000 feet deep. According to Russell ^ solid rock is exposed only in the canyon waUs which in many places rise nearly vertically from the talus slopes at their base. He believed that the canyon was formerly filled with gravel and that the work of reopening the bed is not yet completed. The gradient below Lewiston is about 2.5 feet to the mile, but many rapids inter- rupt the smooth flow of the stream. The soil in the Washington part of the Snake River basin is fine and deep and is practically free from pebbles, and where only a sparse desert growth exists it is readily swept by the winds into great dunes. The depth and richness of the soil, however, render it eminently suitable for agriculture, and though the plateau has a forbidding, desert-Hke aspect, it is capable of producing abundant crops when it is properly watered. Precipitation is heavy in the mountain portion and is mostly snow, but in the lower valleys it amounts to only 8 or 10 inches a year. The temperature of the central valleys ranges from about 100° or higher in summer to considerably below zero in winter. There are many sites along Snake River where immense amounts of power can be developed, but few have yet been utilized. Power plants are in operation on Snake River at American Falls, Shoshone Falls, and the Minidoka dam, and on Payette and Boise rivers, tributaries of the Snake. CHARACTER OF THE WATER. Samples of water were collected from Snake River at the Northern Pacific Railway bridge near Burbank from March 13, 1910, to Janu- ary 31, 1911, inclusive, by Albert Ellis, station master at Burbank. A gaging station is maintained at the same point, above which the drainage area is 109,000 square miles. The quaUty of the water is subject to considerable variation, according to discharge. The turbidity of a stream may be expected to increase with rising flood and to decrease after the first flood waters have passed. Dissolved matter may be expected to decrease with rising stage and to reach a minimum at or shortly after the max- imum flood stage, when the disintegrated rock material and other partly soluble matter that has accumulated on the drainage area during low water has been thoroughly leached. Thus a rise in stage is attended by a quick rise in turbidity with early maximum and slow decline and a slower decrease in dissolved material, the minimum often 1 Russell, I. C, A reconnaissance in southeastern Washington: U. S. GeoL Survey Water-Supply Paper *, pp. 15, 21, 1897. 74 QUALITY 0¥ SURFACE WATERS OF WASHINGTON. being apparent during falling stage. The analyses of Snake River water clearly exemplify these conditions. The first crest of the spring freshets occurred at about the time of the highest turbidity; after a slight drop another rise took place, not quite so high as the first but of longer duration and unaccompanied by increased turbidity. Sus- pended matter reached a minimum almost a month after the date of the first flood and during the second one; a second but less pronounced low value is recorded during the falhng stage in June. Maximum dissolved matter occurred during the first stages of the autumnal rise, when the first leachings of the summer accumulations of soluble matter were brought down the river. The seasonal variation of dis- solved matter is about one and a half times the minimum content. The water of Snake River at Burbank is usually turbid and should be clarified before being used for drinking or manufacturing; its aver- age hardness is about 70 parts per million. It would not corrode boilers or cause foaming under ordinary conditions of operation. If it were used in boilers without sedimentation it would deposit about IJ pounds of medium soft scale per 1,000 gallons of water injected. Treatment in a preheater or by sedimentation is all that is advisable as preliminary to its use in boilers, and unless large amounts of steam are generated it would probably be most economical to omit all treat- ment and to rely upon occasional cleaning to remove the sludge. The daily alkahnity, as shown by the table, varies within rather narrow hmits, but the color varies with great irregularity. High color is caused chiefly by the washing of humus, in spring from the upland soils and in autumn from the autumn-plowed lands of the lower parts of the basin. The spring maximum is the greater. The turbidity, color, and alkahnity indicate that coagulation and filtration would be advisable if the supply were purified for municipal use. COLUMBIA EIVER BASIN. 75 , CD ® P<^ 3 rt 03 c «3 OOOOOOOOOOOOOMCOOOOOOOO'^OOOOOOOt»-HM OOOOOOO'-<'-IO-^C-»-'5 0DC<50fOOCOl>-eOt>'J>'OiOfO-^e^O-^Oi-lOi-loCOS<3-OOiO»0'^COTPC»OOOC<5COOfOI>'-^t^COO(M(33CiOOCOCCOTri-lO»0.-l ooocie>0-HOO (NO(>»I--tC>0>Oi000030C300!NCCrO'3'>--l->?nOt^t^iO;COT}oooioevieo»oc<)(Mi-4»-it»oooc<5oo»-'5 oocx) c«3M'oioi>^t~^ao'ooi-iT-ic<5coeofoo6odcx5oo eo ec ■^ •* 1-1 CO • oom CO go Eh El c4 gi-i 1-5 1-J Eh . o o o , — cj c^ c3 c3 Ul (1 tH tl £h&^Eh en ' p3 D 2;gO I 0) ®^ *-• -^ "7? ^ «3 sS.SiO QOOOOOOOOOOOOOOOOCOOOOOOOOOOOOOOOO TfO>Oi-ICOOO-*IN (N o 05 00 00 05 05 as oJodcxJoioio cor- ooio03 0T-ioot>.i>icco»0'«tiio'©io-05C5COI>-'^-*»0'Oi-ITjtt>.OI>-C<>OCOOOOMt-^x>^t^^^t-^^^t>It^u3cd>olOOO?o^^ tOrr -1. S-^ ■ C3 • c3 03 En &^E-i 03 -rj ^ f^ C ra O-r; w a> I O oj N O 1-1 rH tH N CO to CO N 'S' i-l C«5 T-l i-l rM C-e^i-((MC>iiO'*50Tjooo>ooo>oQO»oooooioooi-to^coco •^ 00 to !0 -^ r-i r-U-l es i-t Ol C<> tH i-l 1-1 ?0 »H (N 1-1 CO O C<1 1-1 CS r-< 1-1 CO 05 «0 tH oooocoo505a50ooooooooooot>-i~^t^i>.t^t~-.cocooi-i 1-1 cs CO 1-1 (M CO 1-1 (N CO 1-1 (N i-i e5 CO 00 (M »-i -^oot^o>rt»rtt»<35e^t^OOoooooo-^»rt-Hi«iccooo (MC^Tticoo-*coeocoeocoenoo5ioc«oc>»05«0'!)i00oiO'rreci-H000500c30ooooj050occ»o«oi eoco-«0IOC^i--*»-( tH »-t i-l t-< rH C4 1-4 C^ 1-^ 1-H 1-H rH i-( i-( i— I ■Bso r^n © (.4 t^ CO lO C» i-< CD t^ »0>0e<3»0N»H t^»-^ooo^^oa>oo P< S?Q. •<* CO I e<3 CO 00 »o i-t CO OS C3.20 ir5.-ioooc-r^P3-^oooiT»(oOi-(Ooo-<*<<-ie<>05cDoooioocoi-iTriirtt>.i«co TrwoTPiC'^'*'^eoeoeceO'^'«»Tfi'<*c^cdcd^^od^^lO^C"i"3cOodlrfcdcd»CCDU5c0^rfcOt^cOc0^riu5'Ccd»OcOc0^^t^ COC3) CO 00 00-^iOO>CCOr»0505C^TjC^OO'ic^t>^t^ l^^cdo6cd>o'rflOldcdlOt-^^^co^^co^rfcDcdo5coc6l>^^^^u^o6o5cDo6ojodo3o6 1-4 lO o » ® S o c ffl "iQcOTtiQCOONOOOCON-HCOt^OWCOQOiOQOcDcOOOOt^t^iOOOCOcOOO" coot^ob^eooo»oi«-^i-400oooioooc>cooocor-4cooo^o-Hi.-5 0oc>^.t» oiNoocOTtt N 1-1 1-1 W iH 1-4 1-1 N 1-1 iH CO 2 "^ l00oooooiOiOloooooooooooo^^^^^^t^^"t^cococo»-^ Q4 < 3 (^ »Hi-4t-icOCOCO(NC^(NC<>C<)C<)^^ i-i(N i-4csi 1-ico j-(fq »H N 1-4(N CO 1-1 !>» CO oooosospioioioioooooooooooot^t^r^ > o> o^ o^ o^ 1-lN T-l • o O " cii-iC5C30050t-t^t^ooooxocooooooxoot>'t>t»t>»oot>'t^t^oooooooMxooooooi> tDoo<^^e^■«f^c>5oo■^ffO®1-H1-ll-^oocoTt*-^Mrfti-^iOo5i-(OrfM»HTro6o^^ ^_j —d ^^ ^^ ^^ ^^ ^^ ^^ ^^ ^^ ^id ^^ ^^ 125 th t» Tjt eq ■>»i t- I-- ^^ ^^ ^^ ^^ ^^ ^^ ^^ ^^ _^ ^^ ^^ ^^ ^^ co«o«oe<5eo!OCs'e)'^e.®t>-t^t^«t~r-r-t>t^osO!OOcD!OOt^tDt-t^t»t't>-i>-t»t»»o •c^ooooooooooooooooooooooocoooooooooo 05C>c;c:«oooociOc;o«C!»--^' t-i (^t-^o(5» O odo ® c S o s 2 ftS Eh O <-!»-( CO ci i-< ® lo »o -H eq T-< i-H T-i ^ cq CO ^ CO 9 > 03 O O td o < ON •«*< C<1 -^ . © Ci-4i-ieOe4i-li-lTHi-liOC4COC4C<)Cqi-iT-lcqiO oocqc^c<»T-ti-i»-iT-iT--t>-i>-t^i>-:s?sa5-H T-i eq TH es i-H eq i-i w eo i-h c i-i cs i-h cs) i-hcsco ft 1^ l-S 1-5 3 <5 ft ^ C; '-i»H^eccocoe^c<«!Mcqei^ i-i(M T-ieS ,-!€<» i-iC« T-ilN riCSCO'-HINfO 1-I01 >— C-l C^ -l .^^.^.^.s ^^ -. 03 03 oooooooo •"fiOCSOiOOOO ■<*<0000t^-<>..^ ^^ s.^ W' OOOOOOOOO0C-Hr-^C0OOC0C^05iOOlO00C0 --lOO-^CO •O CO > ■o « o o CQ CO o -t-OOt^C-l>-OOt~t^C35t— t^oor^t^t^t^ooooocoooooooooooo 10"*0.-ICOCOOOOO cot~»oooo«coeoeiJoo-<*<-*«eO'*too>e<500»oo5t>-»ciccooce^t^odo3odt>it>^t^t^odo5^.-iO.-i.-H-*.-iF-t^eococooou3oococo«0'i^o^-^l«od^>^^^kO'OlOcoa>ooo>oi"5ooocoT«H,-iTti^(N(Mrt(Moooo-<*i'*c£0«oo->*' ■^co-**co»OT)i-«j?T^Tr-9'-iiioid o © t^050500O»O»(N /■-. ^-1 j^ /^ /^-. y*^ /^ /r^ '■^ *"* '^ ^^ '"^ ""^ ^"^ OO ^ ^ C^ CO T-H _■ ^' ^* ^' -• *— t »— ( ©©©©©©®©0<— ;<—)©(— )Cl(—,{-^r-)0000©©©©©00 • 03 tH ;-i ii k4 (i ii ;-i ^ H rH Eh H H E-i H ;. ^ Ui 1^ (h ^&HtHeHE-l e a a g «tC ^H-^,-l?O000OTt<.-l OOOOO «OIMO OO 5£ (N e^ot^o6'-l■^^-io^Hco-^e>^Tl0'-HT-icoc<)!N^>-ico-*e<)coc^T-H-.ti(N!M.-He^coco, ■ a c « © C8 1-1 es CO i-i M CO 1 ft 03 l(N i-H (N fM A < a ^ tuo <5 86 QUALITY OF SUEFACE WATERS OF WASHINGTON. Color and alkalinity of the water of Columbia River at Pasco. [Parts per million.] Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCOs). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Mar. 13 45 49 45 46 24 36 16 26 20 4 6 6 6 6 8 6 4 8 6 10 6 6 6 6 a Trace. 0.0 .0 .0 .0 .0 .0 .0 .0 ol3 015 .0 a 15 ol4 ol7 .0 .0 a 16 ol3 a 9.1 .0 05.5 .0 .0 68 73 71 73 70 71 66 62 66 36 37 65 32 30 37 61 64 26 37 37 76 66 70 65 1910. May 21 10 16 4 4 16 4 50 6 4 12 8 8 4 4 20 8 0.0 .0 .0 Trace. .0 .0 .0 .0 .0 Trace. .0 .0 .0 Trace. .0 .0 .0 .0 .0 .0 .0 .0 .0 65 14 22 65 15 23 66 16 24 63 21 25 62 23 26 63 25 27 68 28 28 60 30 29 66 May 4 30 66 ^ 6 31 69 7 ■ June 1 67 8 2 67 9 3 76 10 4 76 11 5 67 12 6 68 13 7 65 14 8 69 16 9 66 17 10 67 18 11 68 19 12 67 20 o Abnormal; probably present as HCO3 at time of collection. COLUMBIA RIVER AT CASCADE LOCKS. GENERAL FEATURES. Cascade Locks are situated on the Oregon side of Columbia River, nearly opposite Stevenson, Wash., 35 miles below The Dalles, at a place where the river flows in a deep, narrow gorge cut through the basalts of the Cascade Mountains and over a basalt ledge in a series of rapids known as the Cascades. The river at this place is now almost at grade, and at low water the river at The Dalles is only 45 feet above mean sea level. Cascade Locks, therefore, mark the lowest place on Columbia Eiver unaffected by tides, and consequently the lowest place where representative samples of water and trust- worthy discharge measurements could be obtained, though the cur- rent much nearer the mouth is strong enough to prevent the water from becoming saline. The largest tributaries of Columbia River between Pasco and Cas- cade Locks are, from the west and north, Khckitat River and White Salmon River, and from the east and south, Snake, Walla Walla, Umatilla, Willow, John Day, Deschutes, and Hood rivers. These streams contribute more than 35 per cent of the discharge at Cascade Locks. Analyses of the water of Khckitat and Snake rivers are given on pages 79 and 75, respectively. The waters of Umatilla, John Day, and Deschutes rivers and their tributaries were studied in 1911 and 1912 in cooperation with the State engineer of Oregon. COLXJIMBIA EIVER BASIN. 87 CHARACTER OF THE WATER. Samples of the water of Columbia Kiver were collected daily at Cascade Locks from March 13 to December 31, 1910, and from August 1, 1911, to August 14, 1912, in the swift current above the rapids. The collections were made by Val W. Tompkins, inspector at Cascade Locks, through the courtesy of the district engineer of the Engineer Corps, United States Army. Samples could not be collected between January 3 andJanuary 18, 1912, because there was no reason- ably safe place at which containers could be lowered to flo^^ing water through the ice. The estimates of discharge included in the table of analyses have been computed from those obtained at the gaging station at The Dalles by correcting them for the difference in drainage area. The basin of Columbia River above The Dalles covers 237,000 square miles and above Cascade Locks only 2,600 square miles more. ^ 88 QUALITY OF SURFACE WATERS OF WASHINGTON. p< m C3 c3 C 03 Q—! C3 C m 53^2 Iz; -l«5IMi-lOOOlOt^OOOO-«»Ot^00005 (NcOCoeceO'*coo»ccoooc^OOOOO c4FHC-3c4i-H *i^ * 'i-J 'T-;.-000"*fl5 r-<(NCO-^CC(NCOIMlOOIM05<35a>oot^oot^co«o«Da>t^ »COOOSiOiO-^-<*<-*iOi-i^e^.-l cS CO-"** 00 O0O0C-l 1-1 t-H .-I 1-1 IM C^ »C r-1 C<) CO .t^l^-^ <5 s « -3 3 3 Hs l-S be 9< Ph -< c3 3 3 3 OCO r-l O t^ 00 3 T3 • a ■ ■»-< • o 3 (U -c3 U) "^ d o &5 ft bJO d 3 T3 COLUMBIA EIVER BASIN. 89 to rs « (H % oi c3 d 03 T3 «-i © rn C o3 c3 ^ ooooooooooooooooooooooooooooooooooooo C^iOoOOOOOOOOOO'OO'OO — 0C>lu;O0000O0OO000O0OO0 ■<*-oO'rooicoO'-HOcoooo50>«i005'0 05i-iOO-HOCO'OOt^03fOO-H-HOO^»0'— iMO«OTt<-<*<003Cou5i-iooet-o'*-t»OOI>'t-t-COt^O>03--ieOO>t^OC'— 'C50-^C^---H-t^eS05 ,_( r-l ■— I ,-( 1-1 T-li-lrH r-H ,-1 (M C^ CC^ «0 ?0 IC iO M (M e<» r-l ft-3' Ob-ooor00o0000-*a500roe»e<3t^eo»«-^t-coo«o 03 cS.Hb 000000000000000 o ® oJoJtocoodoJOJi-it^i-ioooO'-ie^ iCC000005-OOO. ^3 OMOOCOiOiOOOOOCOMTttOJOO-^e^ltOtOiOM ■* tH N Oi -"f O 35 O 50 05 ■*! oooooo-* ajc^oooooo ©00000 i-< 00 . lO ->*'^coto?dcoc«5 ■^cOe<100050000Tit^-^'*-^<»io»o-*t^t^ooo>ooo> © to M© s^S ©T3 >'?n eS © •a:;; m3 Oi^ UxJ a T3V- © a-fl m u S ..ll aS* sfl rP.y n OS > a &a •, Vh D T3T3 <11 <» )-i a •0 p,© . af^ c» u J3 •9ri a © ^ -^ 03 l:i P^-^ *»-« rt 3 fl ca © © t/JXJ 5fi-H ^ 2i 03 73 m2 CM a m VI ^l'*! « •^ 90 QUALITY OF SURFACE WATERS OF WASHINGTON. The water is suitable for most industrial uses, as it is low in min- eral content, belongs to the calcium-carbonate type, and is character- ized by temporary hardness and by low permanent hardness. Its content of scale-forming ingredients might be decreased somewhat by preheating or by adding small amounts of lime, but that treatment is unnecessary, because the scale which would be deposited is small in amount, soft, and easily removable from boilers. The water might cause corrosion under some conditions, but trouble from that cause would be sUght. The water is excellent for irrigation, for which a large amount of it will probably be used along the river above The Dalles on large areas of arid land which can be made very productive if they are suppUed with water. It will be practicable to pump the water to these lands as soon as cheap summer power is developed at such places as Celilo, on the Columbia, or the falls on the upper Deschutes. Columbia River is more highly mineralized at Cascade Locks than at Pasco, and the differences in character involve increases in propor- tion of sihca, alkahes, and chlorides and decreases in proportion of alkaline earths and bicarbonates. Most of these changes can be ex- plained by the influence of Snake River, for Umatilla River and John Day River, though more highly mineralized than Columbia River, dis- charge to it relatively small amounts. The increase in content of sihca between Pasco and Cascade Locks, which is not proportionate to the other changes, is probably due to the introduction of larger amoimts of this substance by aU tributaries, because those entering below Pasco are all highly siliceous. The changes in mineral content between Pasco and Cascade Locks and the chemical composition of the water of Snake River are summarized in the following table: Average quality of the water of Columbia River at Pasco and at Cascade Lochs and of Snake River at Burbank. [Parts per million.] Columbia River at Pasco, 1910. Columbia River at Cascade Locks, 1910. Columbia River at Cascade Locks, 1911-12. Snake River at Btu-bank, 1910. Suspended matter Silica (SiOg; Iron(Fe) Calcium (Ca) Magnesium (Mg) Sodium and potassium (Na+K) Carbonate radicle (CO3) Bicarbonate radicle (HCO3) Sulphate radicle (SO4) Nitrate radicle (NO3) Chlorine (CI) Dissolved solids 6.7 7.7 .04 18 4.5 6.0 .0 73 11 83 52 13 .04 16 4.2 7.1 .0 67 13 .43 2.0 89 40 14 17" 3. 8. 69' 12 3! 97 .06 9 9 52 19 .05 19 5.6 14 .0 83 21 .53 8.1 131 The water of the lower Columbia is mixed drainage from a very extensive basin, the upper part of which contains large amounts of Paleozoic and older sediments, now more or less completely metamor- COLUMBIA BIVER BASIN. 91 phosed, and the lower chiefly basalts and other lavas. The water of Columbia River at Northport exhibits secondary salinity. The water of the river at Pasco Ues near the border between secondary saline and primary alkaline water. Columbia River at Cascade Locks is also in the border class, but is more nearly in the class of secondary saline waters, for the average of all the analyses shows it to have a slight excess of strong acids over alkalies, though it had very slight primary alkalinity in 1911-12. The effect of the addition of primary alkaline waters in Washington and Oregon is to destroy the secondary salinity of the water of Colimabia River at Cascade Locks, but not to give it pronounced primary alkalinity. The values of sodium and potassium in the accompanying analysis of water of Columbia River at Mayger, Oreg., about 30 miles above the mouth, are evidently erroneous, as the excess of potassium over sodium content is entirely abnormal for river waters of North America. The average potassimn content of seven composite samples from the same source, each of which represents one month's water, is reported in a private communication from the director of the Oregon Agricul- tural College experiment station as 0.97 part per million, which is in accord with the writer's determinations on water from Cascade Locks. If sodium is corrected to 6.5 and potassium to 1.6 parts per million, the analysis indicates that the water of Columbia River at Mayger is characterized by primary alkalinity. This is chiefly the result of the addition of the primary alkaline waters of Willamette River and Lewis River, which drain regions where volcanic rocks predominate Analysis of water of Columbia River at Mayger, Oreg., in August, 1909. (^ Percentage of anhy- drous residue. Silica (Si02) Oxide of iron and alumina (AlaOa+FeaOs) Calcium (Ca) Magnesium (Mg) Sodium (Na) Potassium (K) Ammonium radicle (NEU) Bicarbonate radicle (HCO3) & Sulphate radicle (SO4) Chlorine (Cl) Phosphate radicle (PO4) Total solids at 180° C 4.6 4.2 16.8 4.8 7.7 7.9 .8 C31.8 10.6 10.6 .2 a Analysis by B. Pilkington: Oregon Agricultural College Experiment Station Bull. 112, 1912. fc Computed from reported CO3. c Computed as CO3. Determinations of color and alkalinity of the water of Columbia River at Cascade Locks, Oreg., were made daily from March 15 to December 30, 1910, inclusive, when samphng was temporarily dis- continued. All carbonates were probably present as the bicarbonate radicle when the samples were collected, as reactions before analysis doubtless convert part of the bicarbonate alkalinity to normal car- 92 QUALITY OF SURFACE WATERS OF WASHINGTON. bonate alkalinity. Such change explains the difference between the amount of normal carbonates reported for the daily samples and that for the 10-day composite samples. The total alkahnity, which is correct, did not vary greatly and it was always sufficient to react with the quantity of coagulant or disinfectant that might be intro- duced in connection with filtration. Early in the spring the water was noticeably colored; during the rest of the year it was nearly colorless, but only once did colorimetric determinations show a complete absence of any tint. Color and alkalinity of the water of Columbia River at Cascade Locks. [Parts per million.] Date. Mar. 1910. Apr. May 9. 10. 11. 13. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. Color. 43 54 40 40 38 36 44 54 54 70 96 90 62 88 32 32 28 32 26 20 12 8 24 20 20 32 16 24 16 20 14 16 12 10 8 14 8 10 12 16 8 12 12 16 12 14 12 12 Carbon- ate radicle (CDs). 0.0 .0 a7.2 a 14. .0 .0 a4.3 .0 .0 .0 a 1.2 .0 a Trace. .0 a Trace. .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 a9.1 a2.4 .0 .0 .0 .0 .0 .0 - .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 a 14 a 12 a 20 ol2 oil a 14 o25 a 12 a 25 .0 o8.2 ol4 a6.7 all Bicarbon- ate radicle (HCO3). 56 73 65 60 62 65 62 66 62 63 68 62 67 60 62 57 65 62 59 63 68 65 65 66 67 58 68 63 65 69 67 72 73 64 57 57 57 54 52 50 26 28 17 33 42 32 18 40 9. 59 41 27 42 35 Date. May 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 30. 31. June 1. 2. 3. 4. 5. 6. 7. 1910. July 10. 11. 12. 13. 14. 15. 16. 17. 18. 20. 21. 23. 24. 25. 29. 4. 6. 9. 10. 11. 12. 16. 18. 19. 20. 21. 22. 23. 25. 26. 27. 28. Carbon- Bicarbon- Color, ate radicle ate radicle (CO3). (HCO3). 8 013 28 16 .0 70 16 a 17 23 14 .0 71 6 a 29 15 10 a 20 32 8 020 22 12 a 12 50 12 .0 69 6 a 12 42 6 07.4 46 10 .0 68 8 .0 56 6 .0 57 6 a Trace. 58 6 04.8 54 8 .0 61 8 a7.2 52 8 .0 54 14 .0 62 10 .0 57 8 .0 60 10 a2.4 63 8 al.2 65 30 .0 62 8 .0 63 8 .0 64 8 .0 62 8 .0 64 8 al.2 64 12 .0 62 14 0I.2 61 16 .0 63 8 al.2 63 10 .0 65 16 .0 67 8 .0 68 7 .0 70 6 .0 69 8 .0 76 8 .0 68 8 03.6 63 8 .0 72 11 .0 67 8 07.2 52 10 0I.2 67 8 .0 67 8 0I.2 67 10 .0 67 7 07.2 56 15 .0 41 17 .0 40 8 .0 67 8 .0 69 8 .0 70 8 .0 69 4 .0 68 a Abnormal; probably present as HGO3 at time of collection. CHEMICAL COMPOSITION OF KIVER WATERS. 93 Color and alkalinity of the water of Columbia River at Cascade Locks — Continued. Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). Date. Color. Carbon- ate radicle (CO3). Bicarbon- ate radicle (HCO3). 1910. Tnlv 2Q 7 8 8 16 9 9 8 8 7 8 8 8 48 8 7 7 8 8 8 8 8 8 8 7 7 8 7 8 4 6 4 4 4 8 8 8 8 8 8 8 8 8 8 8 4 0.0 .0 .0 .0 .0 .0 04.8 .0 01.2 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 a 16 a 20 .0 .0 .0 .0 .0 .0 .0 .0 .0 07.2 .0 09.6 19.4 a 12 .0 .0 .0 .0 .0 .0 .0 .0 .0 71 69 70 71 71 72 65 69 68 71 71 69 70 66 66 68 68 65 68 68 68 J8 41 71 71 1910. Oct. 14 4 6 20 8 6 6 6 8 6 4 6 6 4 6 10 6 4 8 4 2 6 2 4 4 2 3 2 16 9 10 8 12 16 8 8 8 8 8 8 10 4 6 8 9 8 0.0 .0 .0 .0 .0 .0 .0 .0 .0 .0 ,0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 . .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 .0 70 30 15 69 31 16 72 Aue. 2 18 70 3 19 71 4 20 71 5 22 69 6 24 72 7 25 72 8 26 68 9 27 71 10 31 76 11 Nov. 2 78 12 4 76 13 5 79 14 6 73 15 7 74 16 8 78 17 ... 10 67 22 11 68 23 12 72 30 21 63 31 22 65 Sept. 1 23 66 2 25 71 3 26 63 6 74 76 77 73 76 73 60 74 57 65 61 77 74 84 78 77 78 67 70 70 28 62 7 29 76 8 Dec. 1 68 10 4 67 12 5 67 13 6 70 14 7 73 16 9 63 17 10 66 23 11 65 24 15 62 Oct. 1 16 68 3.. 17 68 7 19 68 8 22 74 9 23 73 10 24 62 11 29 76 12 30 82 13 a Abnormal; probably present as HCOs at time of collection. AVERAGE CHEMICAL COMPOSITION OF RIVER WATERS. The accompanying table summarizes the chemical composition of the river waters that were examined. Their low mineral content is noteworthy. The muddiest and the most strongly concentrated water, that of Snake River near its mouth, after the stream has traversed an arid plain, contains only 131 parts per miUion of dis- solved and 52 parts of suspended matter. The drainage of the Coast, Olympic, and Cascade ranges, as indicated by analyses of water from Skagit, Cedar, Green, Chehahs, Wynoochee, KHckitat, Naches, Yakima, and Wenatchee rivers, and Wood Creek, carries less than 90 parts per milUon of dissolved solids and several mountain streams frequently carry as Httle as 50 parts. (See ^g. 1, p. 94.) The mineral content of the water of Columbia River is shghtly in- creased between Pasco and Cascade Locks, chiefly by the stronger 94 QUALITY OF SURFACE WATERS OF WASHINGTON. influent, Snake Eiver. That the mineral content and composition at Pasco are practically the same as at Northport is due to lack of appreciable drainage from the semiarid section of the Columbia plains. FiGUEE 1. — Diagram sliowing relative amounts of dissolved and suspended material carried by rivers of Washington. All the waters belong to the calcium-carbonate type — that is, the alkaline earths, calcium and magnesium, and carbonates or bicar- bonates predominate. The content of sulphate is not large and chlorine is very low. Sihca, though not present in very great quan- tity, constitutes, of course, a large proportion of the mineral matter in such dilute solutions. Iron is generally so low as to be almost inappreciable. CHEMICAL COMPOSITION OF RIVER WATERS. 95 :z;2J 02 03 C3 5^6 1^ o.5o o©" -2 C c C M CQ S o © rT-( -U f? C3 "2 e«'^ooo5»-i«oooi'-i«oc. O >-4 OS CO «0 1-1 »o «D ece.COCOCO»C(MCO>-< i-Hi--5rs?Ta;Trcoi-Hcoc4Tri-H»de«5cq-q'co> O O CO O O tX) g:) -ir~)''''^i^fl Q.^>-r>-^ " OOt~-00M-^»0OOt^CiM05C^OO-<*<« p4 00 * * e4 CO oi 1-i " * 1-H o ' ei CO 13^ cc iji ■»»>OOCOCC (>ic5-fl5coTPc4i-5osod»ot-^5d-«i<»oo5i-5e<5t^ e^i-HTj-ooc^c^op^-^ooiosoior^ocio 03»H»oi-iooiOo>Oi-i-3ioc^odoii-5o6o5o6i>^c3odo5050Jo6i-5 i-i(N»oc<5i>'i-H"5Mi>'*«^-*oo»oeqoo ecec>i5'Crii-.a5e4iaiec-<3^co-«r»c»o»Oia*OOOTfli-(i-4THi-(T-ieONOC rt c 2 Jf oQ B t- g 2^ o1l5'2^ g o^ J fi ©S5 S ^Soa^^oss = C.S > °i^M «Q2fi.6oSMZO^Kcoos;Sc;^ ^3 .1^ © © ©(Do ©•^^o-g ■r-i 03 P ©-2 ©^ c3 c3 o S o >>•;§ •d ©.i 000 33476°— wsp 339—14- 96 QUALITY OF SUEFACE WATEES OF WASHINGTON. ECONOMIC VALUE OF THE RIVERS. The streams furnish good water for use in boilers. If the small amount of suspended matter usually carried is removed by brief sedimentation the waters are capable of forming in boilers only one- fourth to three-fourths pound of scale per 1^000 gallons of water con- sumed. The high percentage of silica is Hkely to make the scale rather hard, but not excessively so, and the total quantity of incrus- tants is too small to justify artificial softening of the waters. Certain organic reagents, such as logwood or tannin, are helpful in remedying the trouble caused by sihca, but as those reagents are injurious for other reasons their use ordinarily is not recommended. Foaming would not occur if the customary blowing off is practiced. The free carbon dioxide and the organic matter might possibly cause sHght corrosion under some conditions, but that trouble can readily be obviated by treatment of the waters with a little milk of Hme. The general use of boiler compounds or other reagents is not advisable. All the river waters that were examined are entirely suitable for irrigation and will not noticeably increase the alkali of the soil except on land that entirely lacks drainage. Analyses of the waters from the west slope of the Cascades indicate that the soils in many parts of that region are deficient in Hme, and this conclusion is corroborated by the results of published analyses of the soils. Analyses of the intermountain and eastern waters, however, give evidence that the soils there are not deficient in lime and their marked fertihty accords with that evidence. The surface waters of Washington are much like those of New England in respect to their availability for domestic use. They carry relatively small quantities of somewhat coarse suspended matter. They range from 20 to 70 parts per milhon in total hardness expressed as CaCOg, and may therefore be classed as soft. Many streams are tinted by organic matter derived from peat, swamps, and general decaying vegetation, but they are not so highly tinged as the well- known ''green-tea" waters of New England, though the proportion of color in some is great enough to render advisable removal of it by means of a coagulant during filtration. None of those tested con- tains enough iron or other mineral substance to be perceptible to taste or objectionable for domestic use. The data in the accompany- ing table indicate the characteristics pertaining to general use of the waters. The average, maximum, and minimum colors and alkalini- ties are based on the daily estimates. The reports of turbidity and dissolved sohds probably do not represent the maximum range of those ingredients because they are based on the analyses of 10-day composite samples. The hardness of each water has been computed from the average chemical composition by means of the formula Total hardness as CaC03 = 2.5Ca-f4.lMg. ECONOMIC VALUE OF THE EIVEKS. 97 o g ro CO > m •o < ;3 o ^o is o ^ s CO § i a> S •So CO 00 C3 S fl. ® ci .■SO 0SC0tJ-li-liOl^i w I— i-^i— (I— iTfi— (coiOt— i»— ic^T— It— I .;>— I &^ Eh OOiOOOiOOOOOOiOOO>OOiO CO lO CO 00 03 Ol O (M TJ< o ^ t^ w M . o w o to ;»-i.S 1|a :^U^«i|^cg|d^a- /iiOMPQcBOWSoPH « c3 OXh O ooo ^"^J c3 ►S ;^ -^ f^ p.>: >: >">=? 98 QUALITY OF SUEFACE WATEES OF WASHINGTON. DEXUDATIOX. The materiaL carried in suspension by a river represents loose soil washed in and particles of rock detached from the sides and bottom of the stream bed. Though the removal effected by this washing of the soil is great, it is small in Washington compared with the effects of direct solution and chemical reaction, which are equivalent to an annual removal of 0.0003 to more than 0.001 inch of solid rock material from the entire area. The first table below shows the amount of denudation by suspen- sion and solution in Washington rivers and the number of years required for the removal of 1 inch of rock material from each drainage basin. The second table shows the rate of denudation in the eastern and western Cascade regions, the Columbia plains region, and the whole Columbia River basin. Tons per day of material, as reported in the tables of analyses in the preceding text, has been computed by multiplying together the content of suspended or dissolved matter, the mean discharge during the corresponding period, and the factor 0.00270. The columns of the following table headed * 'Material removed from drainage area in 1 year" express the amount of material carried through the cross section at each station during the year in which samples of water were collected, and the denudation in milhonths of an inch has been computed by dividing tons per square mile per annum by 0.1917. The last column is the reciprocal of the sum of denudation in milhonths of an inch of sus- pended and dissolved matter.^ Denudation hy streams of Washington. Material removed from drainage area in 1 year. Years Drainage Dis- Sus- Dis- Sus- re- quired to re- move 1 inch River. Locality. (square miles). solved pended solved pended Dissolved Suspended (tons (tons (mil- (mil- (tons). (tons). per per lionths lionths square square of an of an mile). mile). inch). inch). Cedar Eavensdale... 149 34,855 2,960 234 19.8 1,221 103 760 Columbia.. Cascade Locks (1910). 239,600 21,510,000 14, 022, 000 89.8 58.5 468 305 1,300 Do .... Cascade Locks (1911-12). 239, 600 17,000,000 7,000,000 7L0 29.2 370 152 1,900 Do Pasco 103,000 11,454,000 1, 208, 200 111 11.7 579 61 1,600 Klickitat. . . Klickitat 1,090 169, 100 36, 920 155 33.9 809 177 1,000 Skagit..... Sedro Wool- ley. Burbank 2,930 756, 100 363,550 258 124 1,346 647 500 Snake 109,000 6, 824, 000 5,049.000 62.6 46.3 327 242 1,800 Spokane . . . Spokane 4,000 404, 900 45,900 101 11.5 537 60 1,700 Wenatcliee. Cashmere 1,200 189, 8:30 55,400 158 46.2 825 241 940 Yakima Clealum 500 108, 460 18,336 217 36.7 1,132 191 820 Do Prosser 5,050 492, 730 120, 193 97.6 23.8 509 124 1,600 1 Dole, R. B., and Stabler, Herman, Denudation: U. S. Geol. Survey Water-Supply Paper 234, p. 80, 1909. INFLUENCE OF NATUEAL FEATURES. Denudation by grand divisions. 99 Hiver. Locality. Years required to remove linch. East slopes of Cascades: Wenatchee Yakima Do West slopes of Cascades: Cedar Skagit East tributaries of Columbia Liver: Spokane Snake Entire basin of Columbia River: Columbia Snake Columbia Cashmere Clealum Prosser Ravensdale Sedro Woolley Spokane B urban k Pasco Burbank Cascade Locks (1910) 940 820 1,600 760 500 1,700 1,800 1,600 1,800 1,300 Denudation is progressing rapidly in the Cascade Mountains. The rate in the basin of Columbia River is slightly less than the rate on the north Atlantic coast/ and the eastern tributaries of the Columbia are much less active than the western tributaries. The eastern tributaries are denuding their drainage areas at about the same rate as the rivers entering the Gulf of Mexico from the west. INFLUENCE OF NATURAL FEATURES. PRECIPITATION. Surface waters from arid regions are more concentrated than those from humid regions, though the latter have greater erosive action and consequently carry away greater quantities of dissolved matter in a given period. This is clearly exemplified by the waters of Washing- ton. The average mineral content of the water of Skagit River, which drains a region of large precipitation, is only 48 parts per mil- lion, while the water of Snake River, which drains an arid region, con- tains 131 parts per million of dissolved soUds. The other rivers examined show similar relationship between rainfall and mineral con- tent. Accumulation of soluble salts takes place where rainfall is very shght because the run-off can not remove the soluble products of rock decomposition as fast as they are formed. WIND-BORNE MATERIAL. The quantities of the soluble products carried by many streams of Washington are so large that the influence of minor features, such as nearness to the ocean, is not noticeable. In the arid regions only the effects of differences of precipitation and Hthologic characteristics are readily discernible. The quantities of sodium and chlorine in surface waters near the ocean are increased by ^ind-borne oceanic salt, 1 Dole, R. B., and Stabler, Herman, op. cit., p. So. 100 QUALITY OF SURFACE WATERS OF WASHINGTON. wMch falls with the rain, and the farther inland the rainfall the less is the amount of this '^cyclic salt." The effect of this addition is not apparent in Washington, except possibly in streams in the coastal basin, ia those flowing from the west slopes of the Cascades, and in the upland waters of the east slopes of the Cascades. In those waters there appears to be relationship between chlorine content and distance from the ocean, but it is not simple and no definite indication of isochlors by means of the available analyses is possible. The daily variations in chlorine are frequently as great as regional differences, Windstorms in some places, as at Cascade Locks on the Columbia, increase the content of suspended taatter chiefly by blowing silt and sand into the streams. The quantity and relative coarseness of the suspended matter in Snake River at Burbank indicate that similar action takes place along that stream. FORE STATION. Forests undoubtedly inhibit the removal of suspended matter by rivers, but they also aid rock disintegration and soil loosening, and thus by their own chemical work and by the greater seepage from areas covered by them increase the amount of dissolved matter in drainage from them. These influences are, however, so involved and information in relation to them is so meager that the effects of forests on mineral content of Washington waters can not now be determined. CHARACTER OF THE ROCKS. The character of the rocks in the drainage basins undoubtedly has great determinative influence on the chemical composition of the waters, though available information regarding the distinctive lithologic characteristics of the basins above the sampling stations in Washington is so meager that generalizations are rather incon- clusive and may even be misleading. In respect to reaction three classes of water have been differentiated in the accompanying table, in accordance with the classi&cation outlined on pages 33-35. Solu- tions in which strong acids exceed alkalies in reacting weight are called secondary saline waters and belong in Class III; those in which alkalies exceed the strong acids are called primary alkaline waters and belong in Class I; and one that is jcharacterized by neither primary alkalinity nor secondary salinity is placed in Class II. The small numerical differences between the reacting weights of the acid and basic radicles are obliterated by assuming that the ratio of Na to K is 4 and by assigning the remaining difference, due mostly to error of analysis, to bicarbonates. The waters of three streams whose basins comprise mostly effusive rocks exhibit notable primary alkalinity. None of the streams has very marked secondary saline characteristics, though half of them. CONCLUSION. 101 possess secondary saline reaction and some of them drain basins that contain extensive areas of sedimentary formations. Primary salinity and secondary alkalinity are highest, the former ranging from 13 to 31 per cent and the latter from 63 to 83 per cent. As the large rivers, however, carry contributions of mineral matter from all kinds of rock — effusive, intrusive, metamorphic, and sedi- mentary — their waters are mixed in type, and analyses of them do not afford bases for very definite conclusions. An extremely well marked effect of lithologic character is the low mineral content of the surface waters of Washington because of the great predominance of igneous rocks and materials formed by their mechanical disintegration. The waters even from the arid section of the State do not approach in mineral content the drainage of some humid regions where soluble sedimentary rocks are abundant* Geochemical classification of surface waters of Washington. River. Locality. Pri- mary sa- linity. Sec- ondary sa- linity. Pri- mary alka- linity. Sec- ondary alka- linity. Class. 25.2 0.7 0.0 74.1 Ill 34.8 13.3 16.5 1.0 4.9 .0 .0 .0 .1 64.2 81.8 83.4 III III I 20.0 3.5 .0 76.5 III 22.6 .0 1.6 75.8 I 25.2 20.8 15.5 20.0 .0 .0 .0 .2 n.5 10.2 13.9 .0 63.3 69.0 70.6 79.8 I I I III 22.1 7.1 .0 70.8 III 29.5 4.3 .0 66.2 TTT 19.9 .0 1.0 79.1 I 27.6 1.6 .0 70.8 m 22.3 23.0 .0 .0 6.3 2.4 71.4 74.6 I I 22.9 3.3 .0 73.8 III 31.2 .0 .0 68.8 II Lithologic character of basin. Cedar Chehalis Columbia Do Do Do Green Klickitat Naches Okanogan Skagit Snake Spokane Wenatchee... Wood (Creek) Wynoochee.. Yakima Do Ravensdale Centralia Northport Pasco Cascade Locks (1910). Cascade Locks (1911-12). Hot Springs Klickitat Naches Okanogan Sedro Woolley ... Burbank Spokane Cashmere Everett Montesano Clealum Prosser Metamorphic and effu- sive rocks. Sedimentary rocks. Metamorphic rocks, etc. Metamorphic, effusive, and sedimentary rocks. Do. Do. Andesite. Basalt. Effusive rocks. Metamorphic and effu- sive rocks. Metamorphic, sedimen- tary, and intrusive rocks. Sediments at h e a d - waters, effusives in lower course. Granitic and basaltic rocks. Metamorphic and sedi- mentary; some intru- sive rocks. Glacial debris. Intrusive and sedimen- tary rocks. Mostly effusive rocks, some sedimentary. Effusive and later sedi- mentary rocks. CONCLUSION. The river waters of Washington are low in mineral content and are good for general industrial use or for irrigation. What little suspended matter they carry is coarse and readily removable. The color of some renders it advisable to purify them by coagulation and rapid sand filtration rather than by slow sand filtration. 102 QUALITY OF SURFACE WATEES OF WASHi:S^GTON. Columbia River enters the State as a secondary saline water, but it receives large additions of alkaline water and finally carries a water of mixed type with a slight tendency toward primary alka- linity. The Cascade Mountain region is being eroded and dissolved at the rate of 1 inch in 500 to 900 years, and the rate of denudation near the summits is nearly equal on both sides of the divide. The rate in the lower altitudes is greater on the western than on the eastern slope and greater in the Cascade intermountain region than in the Columbia plains. The rate in the basin of Columbia River is about 1 inch in 1,300 years, according to the analyses made in 1910. As denudation is not uniform throughout the basin, but is most pronounced in the watercourses themselves, the rivers are deepen- ing and widening their canyons and valleys. No lakes are known whose waters are economically important as sources of commercial salts. Waters from the coulee lakes of Wash- ington contain a greater proportion of common salt than the lake waters of southeastern Oregon and are therefore less valuable for recovery of soda. INDEX. A. Page. Acknowledgments to those aiding S-9, 39 Agriculture, development of 15-16 Alkalies, effect of, in boiler water 21 Alkalinity, determination of 31, 32 range of 97 See also 'particular stream basins. Aluminum sulphate, coagulation bj'^ 27 Analysis, methods of 31 results of, interpretation of 31-35 See also particular stream basins. Angus, D. M., work of 69 Area, extent of 9 Arveson, John, work of 47 B. Barium carbonate, softening by ^ . . 29-30 Bevan, E. J., and Cross, C. F., on paper mak- ing 23 Bicarbonates, effect of, in boiler water 21 Big Bend region, lakes in 12 Bleaching, water for, quality of 21 Breweries, water for, quality of 22-23 Burbank, Snake River at. See Snake River. C. Calcium, scale due to 21 Calcium hydrochlorite, sterilization by 28 Calkins, F. C, on soils of Washington 13 Carbon dioxide, source and effect of 17-18 Cascade Locks. See Columbia River at Cas- cade Locks. Cascade Range, denudation on 99, 102 description of 9-10 geology of 13 Cashmere, Wenatchee River at. See Wenat- chee River. Cedar River, basin of 40-42, 102 basin of, denudation in 44, 99 water of 42-45, 97 analyses of 44, 95 color and alkalinity of 43, 45, 97, 102 geochemical classification of 102 solids carried by 44, 98 Centralia. See Chehalis River at. Chehalis River, basin of 4&-47, 102 See aZso Chehalis River at Centralia. Chehalis River at Centralia, water of 47-51, 95, 97 water of, analyses of 49, 95 color and alkalinity of 47-48, 50, 97 geochemical classification of 102 solids carried by 49, 98 Chelan, Lake, description of 12 Chemical composition of stream waters, data on 93 See also particular streams. Chlorine, occurrence of, in natural waters .... 17, 18-19, 100 Page. Classification of boiler water 31 Clealum. (See Yakima River at Clealum. Climate, description of 11, 13-15 Coagulation, use of, in filtration 26-27 Coast, climate of 14 Color, determinations of 31 range of 96-97