Colorado River

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Short description: Major river in the western United States and Mexico
Colorado River
Horseshoe Bend 13 February 2023.jpg
The Colorado River at Horseshoe Bend, Arizona, a few miles below Glen Canyon Dam.
Colorado River basin map.png
Map of the Colorado River basin
Location
CountryUnited States , Mexico
StatesColorado Colorado
Utah Utah
Arizona Arizona
Nevada Nevada
California California
Template:Country data Baja California Baja California
Template:Country data Sonora Sonora
CitiesGlenwood Springs, CO, Grand Junction, CO, Moab, UT, Page, AZ, Bullhead City, AZ, Lake Havasu City, AZ, Blythe, CA, Yuma, AZ, Las Vegas, NV, Laughlin, NV, San Luis Río Colorado, Son.
Physical characteristics
SourceLa Poudre Pass
 • locationRocky Mountains, Colorado, United States
 • coordinates [ ⚑ ] 40°28′20″N 105°49′34″W / 40.47222°N 105.82611°W / 40.47222; -105.82611[1]
 • elevation10,184 ft (3,104 m)
MouthGulf of California
 • location
Colorado River Delta, Baja California–Sonora, Mexico
 • coordinates
[ ⚑ ] : 31°54′00″N 114°57′03″W / 31.9°N 114.95083°W / 31.9; -114.95083[1]
 • elevation
0 ft (0 m)
Length1,450 mi (2,330 km)[2]
Basin size246,000 sq mi (640,000 km2)[2]
Discharge 
 • locationmouth (average unimpaired flow), max and min at Topock, AZ, 300 mi (480 km) from the mouth[3]
 • average22,500 cu ft/s (640 m3/s)[3]
 • minimum422 cu ft/s (11.9 m3/s)[4]
 • maximum384,000 cu ft/s (10,900 m3/s)[5]
Basin features
Tributaries 
 • leftFraser River, Blue River, Eagle River, Roaring Fork River, Gunnison River, Dolores River, San Juan River, Little Colorado River, Bill Williams River, Gila River
 • rightGreen River, Dirty Devil River, Escalante River, Kanab River, Virgin River, Hardy River

The Colorado River (Spanish: Río Colorado) is one of the principal rivers (along with the Rio Grande) in the Southwestern United States and in northern Mexico. The 1,450-mile-long (2,330 km) river, the 5th longest in the United States, drains an expansive, arid watershed that encompasses parts of seven U.S. states and two Mexican states. The name Colorado derives from the Spanish language for "colored reddish" due to its heavy silt load. Starting in the central Rocky Mountains of Colorado, it flows generally southwest across the Colorado Plateau and through the Grand Canyon before reaching Lake Mead on the Arizona–Nevada border, where it turns south toward the international border. After entering Mexico, the Colorado approaches the mostly dry Colorado River Delta at the tip of the Gulf of California between Baja California and Sonora.

Known for its dramatic canyons, whitewater rapids, and eleven U.S. National Parks, the Colorado River and its tributaries are a vital source of water for 40 million people.[6] An extensive system of dams, reservoirs, and aqueducts divert almost its entire flow for agricultural irrigation and urban water supply.[7][8][9] Its large flow and steep gradient are used to generate hydroelectricity, meeting peaking power demands in much of the Intermountain West. Intensive water consumption has dried up the lower 100 miles (160 km) of the river, which has rarely reached the sea since the 1960s.[7][10][11]

Native Americans have inhabited the Colorado River basin for at least 8,000 years. Starting around 1 AD, large agriculture-based societies were established, but a combination of drought and poor land use practices led to their collapse in the 1300s. Their descendants include tribes such as the Puebloans, while others including the Navajo settled in the Colorado Basin after the 1000s. In the 1500s, Spain explorers began mapping and claiming the watershed, which became part of Mexico upon winning its independence from Spain in 1821. Even after most of the watershed became US territory in 1846, much of the river's course remained unknown. Several expeditions charted the Colorado in the mid-19th century—one of which, led by John Wesley Powell, was the first to run the rapids of the Grand Canyon. Large-scale settlement of the lower basin began in the mid- to late-1800s, with steamboats sailing from the Gulf of California to landings along the river that linked to wagon roads to the interior. Starting in the 1860s, gold and silver strikes drew prospectors to the upper Colorado River basin.

Large-scale river management began in the early 1900s, with major guidelines established in a series of international and US interstate treaties known as the "Law of the River". The US federal government constructed most of the major dams and aqueducts between 1910 and 1970; the largest, Hoover Dam, was completed in 1935. Numerous water projects have also involved state and local governments. With all of their waters fully allocated, both the Colorado and the neighboring Rio Grande are now considered among the most controlled and litigated river systems in the world. Since 2000, extended drought has conflicted with increasing demands for Colorado River water, and the level of human development and control of the river continues to generate controversy.

Course

Headwaters of the Colorado River in Rocky Mountain National Park, Colorado

The Colorado begins at La Poudre Pass in the Never Summer Mountains in Rocky Mountain National Park, 10,184 ft (3,104 m) above sea level.[12] After a short run south, the river turns west below Grand Lake, the largest natural lake in the state.[13] For the first 250 miles (400 km) of its course, the Colorado carves its way through the mountainous Western Slope, a sparsely populated region defined by the portion of the state west of the Continental Divide. As it flows southwest, it gains strength from many small tributaries, as well as larger ones including the Blue, Eagle and Roaring Fork rivers. After passing through De Beque Canyon, the Colorado emerges from the Rockies into the Grand Valley, a major farming and ranching region where it meets one of its largest tributaries, the Gunnison River, at Grand Junction. Most of the upper river is a swift whitewater stream ranging from 200 to 500 feet (60 to 150 m) wide, the depth ranging from 6 to 30 feet (2 to 9 m), with a few notable exceptions, such as the Blackrocks reach where the river is nearly 100 feet (30 m) deep.[14][15] In a few areas, such as the marshy Kawuneeche Valley near the headwaters[16] and the Grand Valley, it exhibits braided characteristics.[15]

From Grand Junction, the Colorado turns northwest before cutting southwest across the eponymous Colorado Plateau, a vast area of high desert centered at the Four Corners of the southwestern United States. Here, the climate becomes significantly drier than that in the Rocky Mountains, and the river becomes entrenched in progressively deeper gorges of bare rock, beginning with Ruby Canyon and then Westwater Canyon as it enters Utah, now once again heading southwest.[17] Farther downstream it receives the Dolores River and defines the southern border of Arches National Park, before passing Moab and flowing through "The Portal", where it exits the Moab Valley between a pair of 1,000-foot (300 m) sandstone cliffs.[18]

A narrow river flows through a narrow gorge flanked by high rocky bluffs
Colorado River in the Grand Canyon seen from Pima Point, near Hermit's Rest

In Utah, the Colorado flows primarily through the "slickrock" country, which is characterized by its narrow canyons and unique "folds" created by the tilting of sedimentary rock layers along faults. This is one of the most inaccessible regions of the continental United States.[19][20] Below the confluence with the Green River, its largest tributary, in Canyonlands National Park, the Colorado enters Cataract Canyon, named for its dangerous rapids,[21] and then Glen Canyon, known for its arches and erosion-sculpted Navajo sandstone formations.[22] Here, the San Juan River, carrying runoff from the southern slope of Colorado's San Juan Mountains, joins the Colorado from the east. The Colorado then enters northern Arizona, where since the 1960s Glen Canyon Dam near Page has flooded the Glen Canyon reach of the river, forming Lake Powell for hydroelectricity generation.[23][24]

In Arizona, the river passes Lee's Ferry, an important crossing for early explorers and settlers and since the early 20th century the principal point where Colorado River flows are measured for apportionment to the seven U.S. and two Mexican states in the basin.[25] Downstream, the river enters Marble Canyon, the beginning of the Grand Canyon, passing under the Navajo Bridges on a now southward course. Below the confluence with the Little Colorado River, the river swings west into Granite Gorge, the most dramatic portion of the Grand Canyon, where the river cuts up to one mile (1.6 km) into the Colorado Plateau, exposing some of the oldest visible rocks on Earth, dating as long ago as 2 billion years.[26] The 277 miles (446 km) of the river that flow through the Grand Canyon are largely encompassed by Grand Canyon National Park and are known for their difficult whitewater, separated by pools that reach up to 110 feet (34 m) in depth.[27]

At the lower end of Grand Canyon, the Colorado widens into Lake Mead, the largest reservoir in the continental United States, formed by Hoover Dam on the border of Arizona and Nevada. Situated southeast of metropolitan Las Vegas, the dam is an integral component for management of the Colorado River, controlling floods and storing water for farms and cities in the lower Colorado River basin.[28] Below the dam the river passes under the Mike O'Callaghan–Pat Tillman Memorial Bridge—which at nearly 900 feet (270 m) above the water is the highest concrete arch bridge in the Western Hemisphere[29]—and then turns due south towards Mexico, defining the Arizona–Nevada and Arizona–California borders.

Top-down view of green agricultural lands surrounded by desert
Satellite view of the Colorado River valley near Yuma, Arizona; Interstate 8 runs from left to right just below center.

After leaving the confines of the Black Canyon, the river emerges from the Colorado Plateau into the Lower Colorado River Valley (LCRV), a desert region dependent on irrigation agriculture and tourism and also home to several major Indian reservations.[30] The river widens here to a broad, moderately deep waterway averaging 500 to 1,000 feet (150 to 300 m) wide and reaching up to 0.25 miles (400 m) across, with depths ranging from 8 to 60 feet (2 to 20 m).[31][32] Before channelization of the Colorado in the 20th century, the lower river was subject to frequent course changes caused by seasonal flow variations. Joseph C. Ives, who surveyed the lower river in 1861, wrote that "the shifting of the channel, the banks, the islands, the bars is so continual and rapid that a detailed description, derived from the experiences of one trip, would be found incorrect, not only during the subsequent year, but perhaps in the course of a week, or even a day."[33]

The LCRV is one of the most densely populated areas along the river, and there are numerous towns including Bullhead City, Arizona, Needles, California, and Lake Havasu City, Arizona. Here, several large diversions draw from the river, providing water for both local uses and distant regions including the Salt River Valley of Arizona and metropolitan Southern California.[34] The last major U.S. diversion is at Imperial Dam, where over 90 percent of the river's flow is moved into the Gila Gravity Canal and Yuma Area Project, and the much bigger All-American Canal to irrigate California's Imperial Valley, the most productive winter agricultural region in the United States.[35]

Colorado River as it exits the United States into Mexico beneath the San Luis Colorado-Colonia Miguel Aléman Bridge (September 2009)

Below Imperial Dam, only a small portion of the Colorado River makes it beyond Yuma, Arizona, and the confluence with the intermittent Gila River—which carries runoff from western New Mexico and most of Arizona–before defining about 24 miles (39 km) of the Mexico–United States border. At Morelos Dam, the entire remaining flow of the Colorado is diverted to irrigate the Mexicali Valley, among Mexico's most fertile agricultural lands.[36] Below San Luis Río Colorado, the Colorado passes entirely into Mexico, defining the Baja California–Sonora border. Since 1960, the stretch of the Colorado between here and the Gulf of California has been dry or a trickle formed by irrigation return flows. The Hardy River provides most of the flow into the Colorado River Delta, a vast alluvial floodplain covering about 3,000 square miles (7,800 km2) of northwestern Mexico.Cite error: Closing </ref> missing for <ref> tag During spring tide conditions, the tidal bore—locally called El Burro—formed in the estuary about Montague Island in Baja California and propagated upstream.[37]

Major tributaries

View of a river winding through a series of narrow gorges that dramatically double back on each other
The San Juan River near Mexican Hat, Utah
View of a brownish river flowing between vegetated banks, with high bluffs rising in the background
The Green River at Mineral Bottom, just north of Canyonlands National Park

The Colorado is joined by over 25 significant tributaries, of which the Green River is the largest by both length and discharge. The Green River takes drainage from the Wind River Range of west-central Wyoming, from Utah's Uinta Mountains, and from the Rockies of northwestern Colorado.[38] The Gila River is the second longest and drains a greater area than the Green,[39] but has a significantly lower flow because of a more arid climate and larger diversions for irrigation and cities.[40] Both the Gunnison and San Juan rivers, which derive most of their water from Rocky Mountains snowmelt, contribute more water than the Gila contributed naturally.[41]

Statistics of the Colorado's longest tributaries
Name State Length Watershed Discharge References
mi km mi2 km2 cfs m3/s
Green River Utah 730 1,170 48,100 125,000 6,048 171.3 [39][42][43][n 1]
Gila River Arizona 649 1,044 58,200 151,000 247 7.0 [2][39][44][n 2]
San Juan River Utah 383 616 24,600 64,000 2,192 62.1 [39][45][46][n 3]
Little Colorado River Arizona 356 573 26,500 69,000 424 12.0 [39][47][48]
Dolores River Utah 250 400 4,574 11,850 633 17.9 [39][49][50]
Gunnison River Colorado 164 264 7,930 20,500 2,570 73 [39][45][51]
Virgin River Nevada 160 260 13,020 33,700 239 6.8 [39][52][53][n 4]

Discharge

In its natural state, the Colorado River poured about 16.3 million acre feet (20.1 km3) into the Gulf of California each year, equaling an average discharge of 22,500 cubic feet per second (640 m3/s)[disputed ].[3] Its flow regime was not at all steady – indeed, "prior to the construction of federal dams and reservoirs, the Colorado was a river of extremes like no other in the United States."[54] Summer peak flows often exceeded 100,000 cubic feet per second (2,800 m3/s), and winter flows fell as low as 2,500 cubic feet per second (71 m3/s).[54] At Topock, Arizona (about 300 miles (480 km) upstream from the Gulf) a maximum historical discharge of 384,000 cubic feet per second (10,900 m3/s) was recorded in 1884, and a minimum of 422 cubic feet per second (11.9 m3/s) was recorded in 1935.[4][5][55][56] Since the construction of Hoover Dam, the lower Colorado rarely exceeds 35,000 cubic feet per second (990 m3/s) or drops below 4,000 cubic feet per second (110 m3/s).[57] Annual runoff volume also varies widely, from a high of 22.2 million acre feet (27.4 km3) in 1984 to a low of 3.8 million acre feet (4.7 km3) in 2002, although in most years only a small portion of this flow – if any – reaches the Gulf.[58][59]

The average annual discharge of the Colorado River has shown a slight but noticeable decreasing trend between 1895 and 2004.
Annual Colorado River discharge volumes at Lee's Ferry between 1895 and 2004

About 85–90 percent of the Colorado River's discharge originates in melting snowpack from the Rocky Mountains of Colorado and Wyoming.[58] The three major upper tributaries of the Colorado – the snow-fed Gunnison, Green, and San Juan – alone deliver almost 9 million acre feet (11 km3) per year to the main stem.[60] The remaining 10 to 15 percent comes from a variety of sources, primarily groundwater and summer monsoon storms.[58] Tributaries in the Lower Basin are prone to monsoon–caused flash floods, but these storms do not often contribute significant volumes of runoff.[58][61] Annual runoff follows snowmelt, which typically begins in April, peaking in May and June before exhausting in July or August.[62]

Due to water diversions, flows at the mouth of the river have steadily declined since the early 1900s. Since 1960, the Colorado has typically dried up before reaching the sea, with the exception of a few wet years.[63] In addition to water consumption, flows have declined due to evaporation from reservoirs and warming temperatures that reduce winter snow accumulation.[64][65][66] Several of the Colorado's major tributaries, including the Gila River, also no longer reach the Colorado due to upstream diversions.[67]

The average flow rate of the Colorado River at the northernmost point of the Mexico–United States border (NIB, or Northerly International Boundary) is 3,869 cubic feet per second (109.6 m3/s), or 2.80 million acre feet (3.45 km3) per year – about one-fifth of what the natural flow would be.[68] Below this location, the remaining flow is diverted to irrigate the Mexicali Valley, leaving a dry riverbed from Morelos Dam to the sea that is supplemented by intermittent flows of irrigation drainage water.[69] There have been exceptions, however, particularly in 1983–1987, when the Colorado once again reached the sea after consecutive seasons of record-breaking snowfall.[70] In 1984, 16.5 million acre feet (20.4 km3) of excess runoff reached the ocean.[71]

The United States Geological Survey (USGS) operates or has operated 46 stream gauges to measure the discharge of the Colorado River, ranging from the headwaters near Grand Lake to the Mexico–U.S. border.[79] The tables at right list data associated with eight of these gauges. River flows as gauged at Lees Ferry, Arizona, about halfway along the length of the Colorado and 16 miles (26 km) below Glen Canyon Dam, are used to determine water allocations in the Colorado River basin.[80] The average discharge recorded there was approximately 14,600 cubic feet per second (410 m3/s), or 10.58 million acre feet (13.05 km3) per year, from 1922 to 2020. This figure has been heavily affected by upstream diversions and reservoir evaporation, especially after the completion of the Colorado River Storage Project in the 1970s. Prior to the completion of Glen Canyon Dam in 1964, the average discharge recorded between 1912 and 1962 was 17,850 cubic feet per second (505 m3/s), or 12.93 million acre feet (15.95 km3) per year.[75]

Drainage basin

Map showing the Upper and Lower Colorado River Basin, and adjacent areas supplied by Colorado River water.

The Colorado River Basin consists of 246,000 square miles (640,000 km2), making it the seventh largest drainage basin in North America.[2] About 238,600 square miles (618,000 km2), or 97 percent of the basin, is in the United States.[39] The basin extends into western Colorado and New Mexico, southwestern Wyoming, eastern and southern Utah, southeastern Nevada and California, and most of Arizona. The areas drained within Baja California and Sonora in Mexico are very small and do not contribute significant runoff.[81] Aside from the Colorado River Delta, the basin extends into Sonora at a few locations further east, including the headwaters of the Santa Cruz River and San Pedro River (both tributaries of the Gila River).[82] For hydrological management purposes, the Colorado River Basin is divided into the Upper Basin (the drainage area above Lees Ferry), and the Lower Basin. The Upper Basin covers only 45 percent of the land area of the Colorado River Basin, but contributes 92 percent of the runoff.[83]

The entire eastern boundary of the Colorado River Basin runs along the North American Continental Divide and is defined largely by the Rocky Mountains and the Rio Grande Basin. The Wind River Range in Wyoming marks the northern extent of the basin, and is separated from the Colorado Rockies by the endorheic Great Divide Basin in southwestern Wyoming. Streams that are nearby the east side of the divide drain into the Mississippi River and Rio Grande, while nearby areas north of the Wind River Range drain into the Columbia River.[82] The western boundary of the Colorado River Basin is formed by various ranges and plateaus that border the Great Basin, including the Uinta Mountains and Wasatch Range. Major Great Basin watersheds bordering the Colorado River Basin are the Great Salt Lake and Sevier Lake watersheds.[82] To the south, the Colorado River Basin borders several watersheds in Mexico draining into the Gulf of California, including the Sonoyta, Concepción, and Yaqui rivers.[82][84] Much of the basin is at high elevation; the mean elevation is 5,500 feet (1,700 m).[81][85] Lees Ferry, more than halfway along the Colorado River from its source, is 3,150 feet (960 m) above sea level.[86] The highest point in the Colorado River Basin is 14,321-foot (4,365 m) Uncompahgre Peak in Colorado's San Juan Mountains, while some water from the river drains via irrigation run-off into California's Salton Sea, 236 feet (72 m) below sea level.[87]

The Black Suspension Bridge crosses the Colorado River in the Grand Canyon at Phantom Ranch, Arizona.

About 72 percent of the Colorado River Basin is classified as arid, with the Sonoran and Mojave deserts covering the southern portion and the Colorado Plateau encompassing much of the central portion.[88] The Colorado Plateau is home to most of the major canyon systems formed by the Colorado River and its tributaries, particularly those of the Green and San Juan rivers. About 23 percent of the basin is forest, with the largest area in the Rocky Mountains; other significant forested areas include the Kaibab, Aquarius, and Markagunt plateaus in southern Utah and northern Arizona, and the Mogollon Rim in central Arizona.[88] These high plateaus and escarpments, often exceeding 9,000 feet (2,700 m) in elevation, form the northern and southern edges of the Colorado Plateau geological province.[89][90] Developed land use in the basin is mostly irrigated agriculture, chiefly in the Grand Valley, the Lower Colorado River Valley, and the Salt River Valley, but the total area of crop and pasture land is only 2–3 percent of the entire basin.[88] Urban areas cover less than 1 percent.[88]

Climate in the Colorado River Basin ranges from subtropical hot desert at southern, lower elevations to alpine in the Rocky Mountains.[91] Mean monthly high temperatures are 25.3 °C (77.5 °F) in the Upper Basin and 33.4 °C (92.1 °F) in the Lower Basin, and lows average −3.6 and 8.9 °C (25.5 and 48.0 °F), respectively. Annual precipitation averages 6.5 inches (164 mm), ranging from over 60 inches (1,500 mm) in some areas of the Rockies to less than 4 inches (100 mm) in dry desert valleys.[83] The Upper Basin generally receives snow and rain during the winter and early spring, while precipitation in the Lower Basin falls mainly during intense but infrequent summer thunderstorms brought on by the North American Monsoon.[92] Precipitation is influenced by the El Niño-Southern Oscillation (ENSO) with El Niño being associated with wetter conditions and La Niña with drier conditions. The effect of ENSO is significantly more pronounced in the Lower Basin, where it has a strong impact on monsoonal rainfall.[83] Runoff patterns across the Colorado River Basin reflect this; most of the perennial tributaries originate in the Upper Basin, while tributaries in the Lower Basin are either ephemeral (such as the Little Colorado River) or highly seasonal (such as the Gila and Salt rivers).[83]

As of 2010, approximately 13 million people lived within the Colorado River basin,[n 6] while about 40 million people live in areas supplied by Colorado River water. Colorado River basin states are among the fastest-growing in the US; the population of Nevada alone increased by about 66 percent between 1990 and 2000 as Arizona grew by some 40 percent.[96] Phoenix, Arizona, Las Vegas, Nevada and Mexicali, Baja California are the largest cities by population within the Colorado River Basin. Other significant cities include Tucson, Arizona, St. George, Utah and Flagstaff, Arizona. Due to the rugged and inhospitable topography through which the river flows, there are only a few major towns along the Colorado River itself, including Grand Junction, Colorado and Yuma, Arizona.[81]

Geology

As recently as the Cretaceous period about 100 million years ago, much of western North America was still part of the Pacific Ocean. Tectonic forces from the collision of the Farallon Plate with the North American Plate pushed up the Rocky Mountains between 50 and 75 million years ago in a mountain-building episode known as the Laramide orogeny.[97] The Colorado River first formed as a west-flowing stream draining the southwestern portion of the range, and the uplift also diverted the Green River, once a tributary of the Mississippi River, west towards the Colorado. About 30 to 20 million years ago, volcanic activity related to the orogeny led to the Mid-Tertiary ignimbrite flare-up, which created smaller formations such as the Chiricahua Mountains in Arizona and deposited massive amounts of volcanic ash and debris over the watershed.[98] The Colorado Plateau first began to rise during the Eocene, between about 55 and 34 million years ago, but did not attain its present height until about 5 million years ago, about when the Colorado River established its present course into the Gulf of California.[99]

The time scale and sequence over which the river's present course and the Grand Canyon were formed is uncertain. Before the Gulf of California was formed around 12 to 5 million years ago by faulting processes along the boundary of the North American and Pacific plates,[100] the Colorado flowed west to an outlet on the Pacific Ocean—possibly Monterey Bay on the Central California coast, and may have played a role in the formation of the Monterey submarine canyon. Crustal extension in the Basin and Range Province began about 20 million years ago and the modern Sierra Nevada began forming about 10 million years ago, eventually diverting the Colorado southwards towards the Gulf.[101] As the Colorado Plateau continued to rise between 5 and 2.5 million years ago, the river maintained its ancestral course (as an antecedent stream) and began to cut the Grand Canyon. Antecedence played a major part in shaping other peculiar geographic features in the watershed, including the Dolores River's bisection of Paradox Valley in Colorado and the Green River's cut through the Uinta Mountains in Utah.[102]

View showing hardened flows of dark volcanic rock descending over the side of a canyon
Remnants of basalt flows from the Uinkaret volcanic field are seen here descending into the Grand Canyon, where they dammed the Colorado over 10 times in the past 2 million years.

Sediments carried from the plateau by the Colorado River created a vast delta made of more than 10,000 cubic miles (42,000 km3) of material that walled off the northernmost part of the gulf in approximately 1 million years. Cut off from the ocean, the portion of the gulf north of the delta eventually evaporated and formed the Salton Sink, which reached about 260 feet (79 m) below sea level.[103][104] Since then the river has changed course into the Salton Sink at least three times, transforming it into Lake Cahuilla, which at maximum size flooded up the valley to present-day Indio, California. The lake took about 50 years to evaporate after the Colorado resumed flowing to the Gulf. The present-day Salton Sea can be considered the most recent incarnation of Lake Cahuilla, though on a much smaller scale.[105]

Between 1.8 million and 10,000 years ago, massive flows of basalt from the Uinkaret volcanic field in northern Arizona dammed the Colorado River within the Grand Canyon. At least 13 lava dams were formed, the largest of which was more than 2,300 feet (700 m) high, backing the river up for nearly 500 miles (800 km) to present-day Moab, Utah.[106] The lack of associated sediment deposits along this stretch of the Colorado River, which would have accumulated in the impounded lakes over time, suggests that most of these dams did not survive for more than a few decades before collapsing or being washed away. Failure of the lava dams caused by erosion, leaks and cavitation caused catastrophic floods, which may have been some of the largest ever to occur in North America, rivaling the late-Pleistocene Missoula Floods of the northwestern United States.[107] Mapping of flood deposits indicate that crests as high as 700 feet (210 m) passed through the Grand Canyon,[108] reaching peak discharges as great as 17 million cubic feet per second (480,000 m3/s).[109]

History

Indigenous peoples

Black and white photograph of a Native American woman holding a child
Navajo woman and child, photographed by Ansel Adams, c. 1944
View of masonry ruins in hilly country
Pueblos and cliff dwellings such as this one in New Mexico were inhabited by people of the Colorado River basin between 2,000 and 700 years ago.

The first humans of the Colorado River basin were likely Paleo-Indians of the Clovis and Folsom cultures, who first arrived on the Colorado Plateau about 12,000 years ago. Very little human activity occurred in the watershed until the rise of the Desert Archaic Culture, which from 8,000 to 2,000 years ago constituted most of the region's human population. These prehistoric inhabitants led a generally nomadic lifestyle, gathering plants and hunting small animals (though some of the earliest peoples hunted larger mammals that became extinct in North America after the end of the Pleistocene epoch).[110] Another notable early group was the Fremont culture, whose peoples inhabited the Colorado Plateau from 2,000 to 700 years ago. The Fremont were likely the first peoples of the Colorado River basin to domesticate crops and construct masonry dwellings; they also left behind a large amount of rock art and petroglyphs, many of which have survived to the present day.[111][112]

Beginning in the early centuries A.D., Colorado River basin peoples began to form large agriculture-based societies, some of which lasted hundreds of years and grew into well-organized civilizations encompassing tens of thousands of inhabitants. The Ancient Puebloan (also known as Anasazi or Hisatsinom) people of the Four Corners region were descended from the Desert Archaic culture.[113] The Puebloan people developed a complex distribution system to supply drinking and irrigation water in Chaco Canyon in northwestern New Mexico.[114]

The Puebloans dominated the basin of the San Juan River, and the center of their civilization was in Chaco Canyon.[115] In Chaco Canyon and the surrounding lands, they built more than 150 multi-story pueblos or "great houses", the largest of which, Pueblo Bonito, is composed of more than 600 rooms.[116][117] The Hohokam culture was present along the middle Gila River beginning around 1 A.D. Between 600 and 700 A.D. they began to employ irrigation on a large scale, and did so more prolifically than any other native group in the Colorado River basin.[118] An extensive system of irrigation canals was constructed on the Gila and Salt rivers, with various estimates of a total length ranging from 180 to 300 miles (290 to 480 km) and capable of irrigating 25,000 to 250,000 acres (10,000 to 101,000 ha). Both civilizations supported large populations at their height; the Chaco Canyon Puebloans numbered between 6,000 and 15,000[119] and estimates for the Hohokam range between 30,000 and 200,000.[120]

Megadrought in 14th century

These sedentary peoples heavily exploited their surroundings, practicing logging and harvesting of other resources on a large scale. The construction of irrigation canals may have led to a significant change in the morphology of many waterways in the Colorado River basin. Prior to human contact, rivers such as the Gila, Salt and Chaco were shallow perennial streams with low, vegetated banks and large floodplains. In time, flash floods caused significant downcutting on irrigation canals, which in turn led to the entrenchment of the original streams into arroyos, making agriculture difficult.[121] A variety of methods were employed to combat these problems, including the construction of large dams, but when a megadrought hit the region in the 14th century A.D. the ancient civilizations of the Colorado River basin abruptly collapsed.[121][122] Some Puebloans migrated to the Rio Grande Valley of central New Mexico and south-central Colorado, becoming the predecessors of the Hopi, Zuni, Laguna and Acoma people in western New Mexico.[110] Many of the tribes that inhabited the Colorado River basin at the time of European contact were descended from Puebloan and Hohokam survivors, while others already had a long history of living in the region or migrated in from bordering lands.[110][123]

Native American names for the Colorado River
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Template:Lang-mrc[125]
Template:Lang-mov[126]
Navajo: Tó Ntsʼósíkooh
Template:Lang-yuf-x-hav /
Sil Gsvgov[127]
Template:Lang-yuf-x-yav[128]

The Navajo were an Athabaskan people who migrated from the north into the Colorado River basin around 1025 A.D.[129] They soon established themselves as the dominant Native American tribe in the Colorado River basin, and their territory stretched over parts of present-day Arizona, New Mexico, Utah and Colorado – in the original homelands of the Puebloans. In fact, the Navajo acquired agricultural skills from the Puebloans before the collapse of the Pueblo civilization in the 14th century.[130] A profusion of other tribes have made a continued, lasting presence along the Colorado River. The Mohave have lived along the rich bottomlands of the lower Colorado below Black Canyon since 1200 A.D. They were fishermen—navigating the river on rafts made of reeds to catch Gila trout and Colorado pikeminnow— and farmers, relying on the annual floods of the river rather than irrigation to water their crops.[131] Ute peoples have inhabited the northern Colorado River basin, mainly in present-day Colorado, Wyoming and Utah, for at least 2,000 years, but did not become well established in the Four Corners area until 1500 A.D.[132][133] The Apache, Cocopah, Halchidhoma, Havasupai, Hualapai, Maricopa, Pima, and Quechan are among many other groups that live along or had territories bordering on the Colorado River and its tributaries.[110][134]

Europeans arrive

Beginning in the 17th century, contact with Europeans brought significant changes to the lifestyles of Native Americans in the Colorado River basin. Missionaries sought to convert indigenous peoples to Christianity – an effort sometimes successful, such as in Father Eusebio Francisco Kino's 1694 encounter with the "docile Pimas of the Gila Valley [who] readily accepted Kino and his Christian teachings".[134] From 1694 to 1702 Kino would explore the Gila and Colorado Rivers to determine if California was an island or peninsula. The Spanish introduced sheep and goats to the Navajo, who came to rely heavily on them for meat, milk and wool.[129] By the mid-16th century, the Utes, having acquired horses from the Spanish, introduced them to the Colorado River basin. The use of horses spread through the basin via trade between the various tribes and greatly facilitated hunting, communications, travel and warfare for indigenous peoples. The more aggressive tribes, such as the Utes and Navajos, often used horses to their advantage in raids against tribes that were slower to adopt them, such as the Goshutes and Southern Paiutes.[135]

Black and white view of two men on the rocky bank of a river
Two Mohave warriors beside the Colorado River in 1871

The gradual influx of European and American explorers, fortune seekers and settlers into the region eventually led to conflicts that forced many Native Americans off their traditional lands. After the acquisition of the Colorado River basin from Mexico in the Mexican–American War in 1846, U.S. military forces commanded by Kit Carson forced more than 8,000 Navajo men, women and children from their homes after a series of unsuccessful attempts to confine their territory, many of which were met with violent resistance. In what is now known as the Long Walk of the Navajo, the captives were marched from Arizona to Fort Sumner in New Mexico, and many died along the route. Four years later, the Navajo signed a treaty that moved them onto a reservation in the Four Corners region that is now known as the Navajo Nation. It is the largest Native American reservation in the United States, encompassing 27,000 square miles (70,000 km2) with a population of over 180,000 as of 2000.[136][137][138]

Mohave expelled

The Mohave were expelled from their territory after a series of minor skirmishes and raids on wagon trains passing through the area in the late 1850s, culminating in an 1859 battle with American forces that concluded the Mohave War.[139] In 1870, the Mohave were relocated to a reservation at Fort Mojave, which spans the borders of Arizona, California and Nevada.[140] Some Mohave were also moved to the 432-square-mile (1,120 km2) Colorado River Indian Reservation on the Arizona–California border, originally established for the Mohave and Chemehuevi people in 1865.[141] In the 1940s, some Hopi and Navajo people were also relocated to this reservation.[142] The four tribes now form a geopolitical body known as the Colorado River Indian Tribes.[141]

Water rights of Native Americans in the Colorado River basin were largely ignored during the extensive water resources development carried out on the river and its tributaries in the 19th and 20th centuries. The construction of dams has often had negative impacts on tribal peoples, such as the Chemehuevi when their riverside lands were flooded after the completion of Parker Dam in 1938. Ten Native American tribes in the basin now hold or continue to claim water rights to the Colorado River.[143] The U.S. government has taken some actions to help quantify and develop the water resources of Native American reservations. The first federally funded irrigation project in the U.S. was the construction of an irrigation canal on the Colorado River Indian Reservation in 1867.[144] Other water projects include the Navajo Indian Irrigation Project, authorized in 1962 for the irrigation of lands in part of the Navajo Nation in north-central New Mexico.[145] The Navajo continue to seek expansion of their water rights because of difficulties with the water supply on their reservation; about 40 percent of its inhabitants must haul water by truck many miles to their homes. In the 21st century, they have filed legal claims against the governments of Arizona, New Mexico and Utah for increased water rights. Some of these claims have been successful for the Navajo, such as a 2004 settlement in which they received a 326,000-acre-foot (402,000 ML) allotment from New Mexico.[146]

Early explorers

La conquista del Colorado (2017), by Augusto Ferrer-Dalmau, depicts Francisco Vázquez de Coronado's 1540–1542 expedition. García López de Cárdenas can be seen overlooking the Grand Canyon.

During the 16th century, the Spanish began to explore and colonize western North America. An early motive was the search for the Seven Cities of Gold, or "Cibola", rumored to have been built by Native Americans somewhere in the desert Southwest. According to a United States Geological Survey publication, it is likely that Francisco de Ulloa was the first European to see the Colorado River when in 1536 he sailed to the head of the Gulf of California.[147] Francisco Vásquez de Coronado's 1540–1542 expedition began as a search for the fabled Cities of Gold, but after learning from natives in New Mexico of a large river to the west, he sent García López de Cárdenas to lead a small contingent to find it. With the guidance of Hopi Indians, Cárdenas and his men became the first outsiders to see the Grand Canyon.[148] Cárdenas was reportedly unimpressed with the canyon, assuming the width of the Colorado River at 6 feet (1.8 m) and estimating 300-foot (91 m)-tall rock formations to be the size of a man. After failing at an attempt to descend to the river, they left the area, defeated by the difficult terrain and torrid weather.[149]

Painting of a company of armed men, some mounted
Coronado Sets Out to the North, by Frederic Remington, c. 1905

In 1540, Hernando de Alarcón and his fleet reached the mouth of the river, intending to provide additional supplies to Coronado's expedition. Alarcón may have sailed the Colorado as far upstream as the present-day California–Arizona border. Coronado never reached the Gulf of California, and Alarcón eventually gave up and left. Melchior Díaz reached the delta in the same year, intending to establish contact with Alarcón, but the latter was already gone by the time of Díaz's arrival. Díaz named the Colorado River Rio del Tizon ("Firebrand River") after seeing a practice used by the local natives for warming themselves.[150] The name Tizon lasted for the next 200 years. The name Rio Colorado ("Red River") was first applied to the Colorado by Father Eusebio Francisco Kino in his maps and written reports resulting from his explorations to the Colorado River Delta and his discovery that California was not an island but a peninsula (1700–1702). Kino's 1701 map, "Paso por Tierra a la California," is the first known map to label the river as the Colorado.[151]

During the 18th and early 19th centuries, many Americans and Spanish believed in the existence of the Buenaventura River, purported to run from the Rocky Mountains in Utah or Colorado to the Pacific Ocean.[152] The name Buenaventura was given to the Green River by Silvestre Vélez de Escalante as early as 1776, but Escalante did not know that the Green drained to the Colorado. Many later maps showed the headwaters of the Green and Colorado rivers connecting with the Sevier River (Rio San Ysabel) and Utah Lake (Lake Timpanogos) before flowing west through the Sierra Nevada into California. Mountain man Jedediah Smith reached the lower Colorado by way of the Virgin River canyon in 1826. Smith called the Colorado the "Seedskeedee", as the Green River in Wyoming was known to fur trappers, correctly believing it to be a continuation of the Green and not a separate river as others believed under the Buenaventura myth.[153] John C. Frémont's 1843 Great Basin expedition proved that no river traversed the Great Basin and Sierra Nevada, officially debunking the Buenaventura myth.[154]

Exploration and navigation below Fort Yuma, 1850–1854

Between 1850 and 1854 the U. S. Army explored the lower reach of the Colorado River from the Gulf of California, looking for the river to provide a less expensive route to supply the remote post of Fort Yuma. First in November 1850 to January 1851, by its transport schooner, Invincible under Captain Alfred H. Wilcox and then by its longboat commanded by Lieutenant George Derby. Later Lieutenant Derby, in his expedition report, recommended that a shallow draft sternwheel steamboat would be the way to send supplies up river to the fort.[155]

The next contractors George Alonzo Johnson with his partner Benjamin M. Hartshorne, brought two barges and 250 tons of supplies arriving at the river's mouth in February 1852, on the United States transport schooner Sierra Nevada under Captain Wilcox. Poling the barges up the Colorado, the first barge sank with its cargo a total loss. The second was finally, after a long struggle poled up to Fort Yuma, but what little it carried was soon consumed by the garrison. Subsequently, wagons again were sent from the fort to haul the balance of the supplies overland from the estuary through the marshes and woodlands of the Delta.[156]:5–9

At last Derby's recommendation was heeded and in November 1852, the Uncle Sam, a 65-foot-long side-wheel paddle steamer, built by Domingo Marcucci, became the first steamboat on the Colorado River.[157]:15 It was brought by the schooner Capacity from San Francisco to the delta by the next contractor to supply the fort, Captain James Turnbull. It was assembled and launched in the estuary, 30 miles above the mouth of the Colorado River. Equipped with only a 20-horsepower engine, the Uncle Sam could only carry 35 tons of supplies, taking 15 days to make the first 120-mile trip. It made many trips up and down the river, taking four months to finish carrying the supplies for the fort, improving its time up river to 12 days. Negligence caused it to sink at its dock below Fort Yuma, and was then washed away before it could be raised, in the spring flood of 1853. Turnbull in financial difficulty, disappeared. Nevertheless, he had shown the worth of steamboats to solve Fort Yuma's supply problem.[156]:10–11

George Alonzo Johnson with his partner Hartshorne and a new partner Captain Alfred H. Wilcox (formerly of the Invincible and Sierra Nevada), formed George A. Johnson & Company and obtained the next contract to supply the fort. Johnson and his partners, all having learned lessons from their failed attempts ascending the Colorado and with the example of the Uncle Sam, brought the parts of a more powerful side-wheel steamboat, the General Jesup, with them to the mouth of the Colorado from San Francisco. There it was reassembled at a landing in the upper tidewater of the river and reached Fort Yuma, January 18, 1854. This new boat, capable of carrying 50 tons of cargo, was very successful making round trips from the estuary to the fort in only four or five days. Costs were cut from $200 to $75 per ton.[156]:11–12[158]:34

Exploration and navigation above Fort Yuma, 1851–1887

Lithograph of Fort Yuma, c. 1875

Lorenzo Sitgreaves led the first Corps of Topographical Engineers mission across northern Arizona to the Colorado River (near modern Bullhead City, Arizona), and down its east bank to the river crossings of the Southern Immigrant Trail at Fort Yuma in 1851.[159][160]

The second Corps of Topographical Engineers expedition passed along and crossed the Colorado was the 1853–1854 Pacific Railroad Survey expedition along the 35th parallel north from Oklahoma to Los Angeles , led by Lt. Amiel Weeks Whipple.[161]

George A. Johnson was instrumental in getting the support for Congressional funding a military expedition up the river. With those funds Johnson expected to provide the transportation for the expedition but was angry and disappointed when the commander of the expedition Lt. Joseph Christmas Ives rejected his offer of one of his steamboats. Before Ives could finish reassembling his steamer in the delta, George A. Johnson set off from Fort Yuma on December 31, 1857, conducting his own exploration of the river above the fort in his steamboat General Jesup. He ascended the river in twenty one days as far as the first rapids in Pyramid Canyon, over 300 miles (480 km) above Fort Yuma and 8 miles (13 km) above the modern site of Davis Dam. Running low on food he turned back.[156]:16–17,19[162] As he returned he encountered Lieutenant Ives, Whipple's assistant, who was leading an expedition to explore the feasibility of using the Colorado River as a navigation route in the Southwest. Ives and his men used a specially built steamboat, the shallow-draft U.S.S. Explorer, and traveled up the river as far as Black Canyon. He then took a small boat up beyond the canyon to Fortification Rock and Las Vegas Wash.[163]:Part 1, 85–87 After experiencing numerous groundings and accidents and having been inhibited by low water in the river, Ives declared: "Ours has been the first, and will doubtless be the last, party of whites to visit this profitless locality. It seems intended by nature that the Colorado River, along the greater portion of its lonely and majestic way, shall be forever unvisited and undisturbed."[164][165]

Until 1866, El Dorado Canyon was the actual head of navigation on the Colorado River. In that year Captain Robert T. Rogers, commanding the steamer Esmeralda with a barge and ninety tons of freight, reached Callville, Nevada, on October 8, 1866.[156]:49 Callville remained the head of navigation on the river until July 7, 1879, when Captain J. A. Mellon in the Gila left El Dorado Canyon landing, steamed up through the rapids in Black Canyon, making record time to Callville and tied up overnight. Next morning he to steamed up through the rapids in Boulder Canyon to reach the mouth of the Virgin River at Rioville July 8, 1879. From 1879 to 1887, Rioville, Nevada was the high water Head of Navigation for the steamboats and the mining company sloop Sou'Wester that carried the salt needed for the reduction of silver ore from there to the mills at El Dorado Canyon.[156]:78

Powell's expeditions, 1869–1871

Up until the mid-19th century, long stretches of the Colorado and Green rivers between Wyoming and Nevada remained largely unexplored due to their remote location and dangers of navigation. Because of the dramatic drop in elevation of the two rivers, there were rumors of huge waterfalls and violent rapids, and Native American tales strengthened their credibility.[166] In 1869, one-armed Civil War veteran John Wesley Powell led an expedition from Green River Station in Wyoming, aiming to run the two rivers all the way down to St. Thomas, Nevada, near present-day Hoover Dam.[167] Powell and nine men – none of whom had prior whitewater experience – set out in May. After braving the rapids of the Gates of Lodore, Cataract Canyon and other gorges along the Colorado, the party arrived at the mouth of the Little Colorado River, where Powell noted down arguably the most famous words ever written about the Grand Canyon of the Colorado:[168]

View of a steep-sided canyon from river level
Marble Canyon, one of the many gorges that Powell's expedition traversed
We are now ready to start on our way down the Great Unknown. Our boats, tied to a common stake, are chafing each other, as they are tossed by the fretful river. They ride high and buoyant, for their loads are lighter than we could desire. We have but a month's rations remaining. The flour has been re-sifted through the mosquito net sieve; the spoiled bacon has been dried, and the worst of it boiled; the few pounds of dried apples have been spread in the sun, and re-shrunken to their normal bulk; the sugar has all melted, and gone on its way down the river; but we have a large sack of coffee. The lighting of the boats has this advantage: they will ride the waves better, and we shall have little to carry when we make a portage.

We are three-quarters of a mile in the depths of the earth, and the great river shrinks into insignificance, as it dashes its angry waves against the walls and cliffs, that rise to the world above; they are but puny ripples, and we but pigmies, running up and down the sands, or lost among the boulders.

We have an unknown distance yet to run; an unknown river yet to explore. What falls there are, we know not; what rocks beset the channel, we know not; what walls rise over the river, we know not; Ah, well! we may conjecture many things. The men talk as cheerfully as ever; jests are bandied about freely this morning; but to me the cheer is somber and the jests are ghastly.
—John Wesley Powell's journal, August 1869[168]

On August 28, 1869, three men deserted the expedition, convinced that they could not possibly survive the trip through the Grand Canyon. They were allegedly killed by Native Americans after making it to the rim of the canyon; two days later, the expedition ran the last of the Grand Canyon rapids and reached St. Thomas.[169] Powell led a second expedition in 1871, this time with financial backing from the U.S. government.[170] The explorers named many features along the Colorado and Green rivers, including Glen Canyon, the Dirty Devil River, Flaming Gorge, and the Gates of Lodore. In what is perhaps a twist of irony, modern-day Lake Powell, which floods Glen Canyon, is also named for their leader.[171]

American settlement

Black and white photograph of a docked sternwheeler with two funnels
The steamboat Mohave No. 2 at Yuma, c. 1876

Starting in the latter half of the 19th century, the lower Colorado below Black Canyon became an important waterway for steamboat commerce. In 1852, the Uncle Sam was launched to provide supplies to the U.S. Army outpost at Fort Yuma. Although this vessel accidentally foundered and sank early in its career, commercial traffic quickly proliferated because river transport was much cheaper than hauling freight over land.[172] Navigation on the Colorado River was dangerous because of the shallow channel and flow variations, so the first sternwheeler on the river, the Colorado of 1855, was designed to carry 60 short tons (54 t) while drawing less than 2 feet (0.6 m) of water.[173] The tidal bore of the lower Colorado also presented a major hazard; in 1922, a 15-foot (4.6 m)-high wave swamped a ship bound for Yuma, killing between 86 and 130 people.[174][175] Steamboats quickly became the principal source of communication and trade along the river until competition from railroads began in the 1870s, and finally the construction of dams along the lower river in 1909, none of which had locks to allow the passage of ships.[176]

During the Manifest Destiny era of the mid-19th century, American pioneers settled many western states but generally avoided the Colorado River basin until the 1850s. Under Brigham Young's grand vision for a "vast empire in the desert",[177] (the State of Deseret) Mormon settlers were among the first whites to establish a permanent presence in the watershed, Fort Clara or Fort Santa Clara, in the winter of 1855–1856 along the Santa Clara River, tributary of the Virgin River. In the lower Colorado mining was the primary spur to economic development, copper mining in southwestern New Mexico Territory the 1850s then the Mohave War and a gold rush on the Gila River in 1859, the El Dorado Canyon Rush in 1860 and Colorado River Gold Rush in 1862.

In 1860, anticipating the American Civil War, the Mormons established a number of settlements to grow cotton along the Virgin River in Washington County, Utah. From 1863 to 1865, Mormon colonists founded St. Thomas and other colonies on the Muddy and Virgin rivers in northwestern Arizona Territory, (now Clark County, Nevada). Stone's Ferry was established by these colonists on the Colorado at the mouth of the Virgin River to carry their produce on a wagon road to the mining districts of Mohave County, Arizona to the south. Also, in 1866, a steamboat landing was established at Callville, intended as an outlet to the Pacific Ocean via the Colorado River, for Mormon settlements in the Great Basin. These settlements reached a peak population of about 600 before being abandoned in 1871, and for nearly a decade these valleys became a haven for outlaws and cattle rustlers.[178] One Mormon settler Daniel Bonelli, remained, operating the ferry and began mining salt in nearby mines, bring it in barges, down river to El Dorado Canyon where it was used to process silver ore. From 1879 to 1887, Colorado Steam Navigation Company steamboats carried the salt, operating up river in the high spring flood waters, through Boulder Canyon, to the landing at Rioville at the mouth of the Virgin River. From 1879 to 1882 the Southwestern Mining Company, largest in El Dorado Canyon, brought in a 56-foot sloop the Sou'Wester that sailed up and down river carrying the salt in the low water time of year until it was wrecked in the Quick and Dirty Rapids of Black Canyon.[156]:78

Black and white portrait of John D. Lee, who established Lee's Ferry across the Colorado River
John D. Lee established a permanent ferry across the Colorado.

Mormons founded settlements along the Duchesne River Valley in the 1870s, and populated the Little Colorado River valley later in the century, settling in towns such as St. Johns, Arizona.[133] They also established settlements along the Gila River in central Arizona beginning in 1871. These early settlers were impressed by the extensive ruins of the Hohokam civilization that previously occupied the Gila River valley, and are said to have "envisioned their new agricultural civilization rising as the mythical phoenix bird from the ashes of Hohokam society".[118] The Mormons were the first whites to develop the water resources of the basin on a large scale, and built complex networks of dams and canals to irrigate wheat, oats and barley in addition to establishing extensive sheep and cattle ranches.[177]

One of the main reasons the Mormons were able to colonize Arizona was the existence of Jacob Hamblin's ferry across the Colorado at Lee's Ferry (then known as Pahreah Crossing), which began running in March 1864.[179] This location was the only section of river for hundreds of miles in both directions where the canyon walls dropped away, allowing for the development of a transport route. John Doyle Lee established a more permanent ferry system at the site in 1870. One reason Lee chose to run the ferry was to flee from Mormon leaders who held him responsible for the Mountain Meadows massacre, in which 120 emigrants in a wagon train were killed by a local militia disguised as Native Americans. Even though it was located along a major travel route, Lee's Ferry was very isolated, and there Lee and his family established the aptly named Lonely Dell Ranch.[179] In 1928, the ferry sank, resulting in the deaths of three men. Later that year, the Navajo Bridge was completed at a point 5 miles (8 km) downstream, rendering the ferry obsolete.[180]

Gold strikes from the mid-19th to early 20th centuries played a major role in attracting settlers to the upper Colorado River basin. In 1859, a group of adventurers from Georgia discovered gold along the Blue River in Colorado and established the mining boomtown of Breckenridge.[181] During 1875, even bigger strikes were made along the Uncompahgre and San Miguel rivers, also in Colorado, and these led to the creation of Ouray and Telluride, respectively.[182][183] Because most gold deposits along the upper Colorado River and its tributaries occur in lode deposits, extensive mining systems and heavy machinery were required to extract them. Mining remains a substantial contributor to the economy of the upper basin and has led to acid mine drainage problems in some regional streams and rivers.[184][185]

Harrison Gray Otis, president of the Colorado River Land Company

The Colorado River region in Mexico became favored place for Americans to invest in agriculture in the late nineteenth century when Mexico President Porfirio Díaz welcomed foreign capital to develop the country. The Colorado River Land Company, formed by Los Angeles Times publisher Harry Chandler, his father-in-law Harrison Gray Otis, and others, developed the Mexicali Valley in Baja California as a thriving land company. The company headquarters was nominally based in Mexico, but its real headquarters was in Los Angeles, California. Land was leased mainly to Americans who were required to develop it. Colorado River was used to irrigate the rich soil. The company largely escaped the turmoil of the Mexican Revolution (1910–20), but in the postrevolutionary period, the Mexican government expropriated the company's land to satisfy the demand for land reform.[186][187][188]

Controversy over the name of the upper Colorado River

The Colorado River did not officially flow through the State of Colorado until July 25, 1921. Prior to that date, the origin of the Colorado River was officially the confluence of the Grand and Green rivers at [ ⚑ ] 38°11′21″N 109°53′09″W / 38.1892°N 109.8857°W / 38.1892; -109.8857 (Confluence of the Green and Colorado rivers) in what is now Canyonlands National Park of Utah. Fathers Dominguez and Escalante named the Grand River the Rio San Rafael in 1776. The Grand River above the confluence with the Gunnison River was also known as the Bunkara River, the Blue River, and the North Fork of the Grand River until the 1870s.

In 1921, U.S. Representative Edward T. Taylor of Colorado petitioned the Congressional Committee on Interstate and Foreign Commerce to rename the Grand River as the Colorado River.[189][190] On July 25, 1921, President Warren G. Harding signed House Joint Resolution 32 - To change the name of the Grand River in Colorado and Utah to the Colorado River,[191] over the objections of representatives from Wyoming, Utah, and the United States Geological Survey, who noted that the Green River was longer and had a larger drainage basin, although the Grand River often contributed a greater flow of water.[189][192][n 7]

Engineering and development

Front view of a dam in a narrow canyon, with water shooting out of the gates
Hoover Dam releasing water in 1998

About 40 million people depend on the Colorado River's water for agricultural, industrial and domestic needs.[194] The Colorado irrigates 5.5 million acres (2.2 million hectares) of farmland,[194] and its hydroelectric plants produce 12 billion kilowatt hours (KWh) of hydroelectricity each year.[195] Hydroelectricity from the Colorado is a key supplier of peaking power on the Southwest electric grid.[196][197] Often called "America's Nile",[198] the Colorado is so intensively managed that each drop of its water is used an average of 17 times in a single year.[199][200] Southern Nevada Water Authority has called the Colorado River one of the "most controlled, controversial and litigated rivers in the world".[201]

Colorado River water allocations, in millions of acre-feet[202][203][204]
User Amount Share
United States 15.0 90.9%
California 4.4 26.7%
Colorado 3.88 23.5%
Arizona 2.8 17.0%
Utah 1.72 10.4%
Wyoming 1.05 6.4%
New Mexico 0.84 5.1%
Nevada 0.3 1.8%
Mexico 1.5 9.1%
Total 16.5 100%

In 1922, six U.S. states signed the Colorado River Compact, which divided half of the river's flow to both the Upper Basin (the drainage area above Lee's Ferry, comprising parts of Colorado, New Mexico, Utah, and Wyoming and a small portion of Arizona) and the Lower Basin (Arizona, California, Nevada, and parts of New Mexico and Utah). The Upper and Lower Basin were each allocated 7.5 million acre feet (9.3 km3) of water per year, a figure believed to represent half of the river's annual flow at Lee's Ferry.[202] The allotments operated under the premise that approximately 17.5 million acre-feet of water flowed through the river annually.[205]

Arizona initially refused to ratify the compact because it feared that California would take too much of the lower basin allotment. In 1944 a compromise was reached in which Arizona was allocated 2.8 million acre feet (3.5 km3), but with the caveat that California's 4.4-million-acre-foot (5.4 km3) allocation was prioritized during drought years.[206] These and nine other decisions, compacts, federal acts and agreements made between 1922 and 1973 constitute what is now known as the Law of the River.[206][207]

In 1944, a treaty between the U.S. and Mexico allocated 1.5 million acre feet (1.9 km3) of Colorado River water to Mexico each year.[203] Morelos Dam was constructed in 1950 to enable Mexico to utilize its share of the river. Water allocated to Mexico from the Colorado River is regulated by the International Boundary and Water Commission, which also apportions waters from the Rio Grande between the two countries.[208]

Transmountain diversions

Large-scale development of Colorado River water supplies started in the late 19th century, at the river's headwaters in La Poudre Pass. The Grand Ditch, directing runoff from the river's headwaters across the Continental Divide to arid eastern Colorado, was considered an engineering marvel when completed in 1890.[209] This was the first of twenty-four "transmountain diversions" constructed to draw water across the Rocky Mountains as the Front Range corridor increased in population.[210] These diversions draw water from the upper Colorado and its tributaries into the South Platte River, Arkansas River and Rio Grande basins.[211] Today, about 80 percent of Colorado's population lives on the Eastern Slope of the Rockies, while 80 percent of precipitation falls on the Western Slope.[212]

The Grand Ditch, one of the earliest water diversions of the Colorado River, is still in use today.

While first planned at the same time as the Grand Ditch, construction on the Colorado-Big Thompson Project (C-BT) did not begin until the 1930s. Today, the C-BT is the largest of the transmountain diversions, delivering 230,000 acre feet (280,000,000 m3) per year from the Colorado River to cities north of Denver.[213] Numerous other projects followed, with the largest including the Roberts Tunnel, which delivers water from the Blue River to the city of Denver,[214][215] and the Fryingpan–Arkansas Project, which diverts water from the Fryingpan River to the Arkansas River basin.[216]

Combined, the transmountain diversions draw about 580,000 acre feet (720,000,000 m3) of water per year out of the Colorado River basin.[211] Historically, most of the water has been used for irrigation, although water usage is increasing for urban water supply and for recreational purposes such as snowmaking and increasing Eastern Slope streamflows for boating and fishing. Denver Water receives about 50 percent of its supply from the Colorado River basin. However, diversions have caused environmental harm to the upper Colorado River system by reducing streamflows in many tributaries.[211] A number of reservoirs have been built to offset the impact of transmountain diversions by storing water for dry season release on the Western Slope, including Williams Fork Reservoir in 1959[217] and Wolford Mountain Reservoir in 1996.[218]

The Imperial Valley and the Salton Sea

In 1900, the California Development Company (CDC) envisioned irrigating the Imperial Valley, a then dry basin on the California–Mexico border, using water from the Colorado River. Due to the valley's location below sea level, water could be diverted and allowed to flow there entirely by gravity. Engineer George Chaffey was hired to design the Alamo Canal, which split from the Colorado near Pilot Knob, California and ran south into Mexico, where it joined the Alamo River, a dry arroyo which had historically carried overflowing floodwaters from the Colorado into the Salton Sink at the bottom of Imperial Valley. The scheme worked initially; by 1903, about four thousand people lived in the valley and more than 100,000 acres (40,000 ha) of farmland had been developed.[219][220]

The Alamo Canal experienced continual problems due to the Colorado's high sediment content and its varying water levels. During low flows, the river often dropped below the level of the canal intake, while high flows silted up the intake, forcing the repeated excavation of new cuts. In early 1905, flooding destroyed the intake gates and water began to flow uncontrolled down the canal towards the Salton Sink. By August, the breach had grown large enough to swallow the entire flow of the river, which began to flood the bottom of the valley. The Southern Pacific Railroad attempted to dam the flow in order to protect their tracks which ran through the valley, but was hampered by repeated flooding.[220] It took seven attempts, more than $3 million, and two years for the railroad, the CDC, and the federal government to permanently block the breach and restore the river's original course – but not before part of the Imperial Valley was flooded under a 45-mile-long (72 km) lake, today's Salton Sea. The Imperial Valley fiasco demonstrated that further economic development of the region would require a dam to control the Colorado's unpredictable flows.[221][222][223]

Boulder Canyon Project

Hoover Dam under construction, 1934
The Imperial Dam (bottom right) diverts water into the All-American Canal (center) running towards Imperial Valley.

A large dam on the Colorado River had been envisioned since the 1920s. In 1928, Congress authorized the Reclamation Service (today's U.S. Bureau of Reclamation, or USBR) to build the Boulder Canyon Project, whose key feature would be a dam on the Colorado in Black Canyon 30 miles (48 km) southeast of Las Vegas, Nevada. On September 30, 1935, Hoover Dam was completed, forming Lake Mead, capable of holding more than two years of the Colorado's flow. Lake Mead was, and still is, the largest artificial lake in the U.S. by storage capacity.[28][224] The construction of Hoover Dam stabilized the lower channel of the Colorado River, stored water for irrigation in times of drought, captured sediment and controlled floods. Hoover was the tallest dam in the world at the time of construction and also had the world's largest hydroelectric power plant.[225]

The Boulder Canyon Project Act also authorized the All-American Canal,[226] which was built as a permanent replacement for the Alamo Canal and follows a route entirely within the U.S. on its way to the Imperial Valley. The canal's intake is located at Imperial Dam, 20 miles (32 km) above Yuma, Arizona, which diverts the majority of the Colorado's flow with only a small portion continuing to Mexico. With a capacity of over 26,000 cubic feet per second (740 m3/s), the All-American Canal is the largest irrigation canal in the world.[227] Because the hot, sunny climate lends to a year-round growing season, the Imperial Valley has become one of the most productive farming regions in North America, providing much of the winter produce supply in the U.S.[8] The Imperial Irrigation District supplies water to 520,000 acres (210,000 ha) south of the Salton Sea.[228] The Coachella Canal, which branches northward from the All-American Canal, irrigates another 78,000 acres (32,000 ha) in the Coachella Valley.[229]

Parker Dam was initially built as the diversion point for the Colorado River Aqueduct, planned by the Metropolitan Water District of Southern California to supply water to Los Angeles.[230] The construction of the dam was opposed by Arizona, which feared that California would take too much water from the Colorado; at one point, Arizona sent members of its National Guard to stop work on the dam. Ultimately, a compromise was reached, with Arizona dropping its objections in exchange for the USBR constructing the Gila Project, which irrigates 110,000 acres (450 km2) on the Arizona side of the river.[231] By 1941, the 241-mile (388 km) long Colorado River Aqueduct was completed, delivering 1.2 million acre feet (1.5 km3) of water west to Southern California. The aqueduct enabled the continued growth of Los Angeles and its suburbs, and provides water to about 10 million people today.[232] The San Diego Aqueduct, which branches off from the Colorado River Aqueduct in Riverside County, California, opened in stages between 1954–1971 and provides water to another 3 million people in the San Diego metro area.[233]

The Las Vegas Valley of Nevada experienced rapid growth after Hoover Dam, and by 1937 Las Vegas had tapped a pipeline into Lake Mead. Nevada officials, believing that groundwater resources in the southern part of the state were sufficient for future growth, were more concerned with securing a large amount of the dam's power supply than water from the Colorado; thus they settled for the smallest water allocation of all the states in the Colorado River Compact.[234] In 2018, due to declining water levels in Lake Mead, a second pipeline was completed with a lower intake elevation.

Colorado River Storage Project

In the first half of the 20th century, the Upper Basin states, with the exception of Colorado, had developed very little of their water allocations from the Colorado River Compact. By the 1950s, however, water demand was rapidly increasing in Utah's Wasatch Front (Salt Lake City metro area) and the Rio Grande Valley of New Mexico, which both began exploring ways to divert water from the Colorado Basin.[235] The Upper Basin states were concerned that they would not be able to use their full Compact allocations due to increasing water demands in the Lower Basin. The Compact requires the Upper Basin to deliver a minimum annual flow of 7.5 million acre feet (9.3×109 m3) past Lee's Ferry (measured on a 10-year rolling average). Without additional reservoir storage, the Upper Basin states could not utilize their allocations without impacting water deliveries to the Lower Basin in dry years.[236]

Glen Canyon Dam, the largest dam of the Colorado River Storage Project

In 1956 Congress authorized the USBR to construct the Colorado River Storage Project (CRSP), which planned several large reservoirs on the upper Colorado, Green, Gunnison and San Juan Rivers.[236] The initial blueprints for the CRSP included two dams on the Green River within Echo Park Canyon in Dinosaur National Monument – a move criticized by both the National Park Service and environmental groups such as the Sierra Club. The controversy received nationwide media attention, and the USBR dropped its plans for the Dinosaur dams in exchange for increasing the size of a proposed dam at Glen Canyon.[237]

The controversy associated with Glen Canyon Dam did not build momentum until construction was well underway. Due to Glen Canyon's remote location, most of the American public did not even know of its existence; the few who did contended that it had much greater scenic value than Echo Park. The environmental movement in the American Southwest has opposed the damming and diversion of the Colorado River system due to negative effects on the ecology and natural beauty of the river and its tributaries. During the construction of Glen Canyon Dam (1956–66), environmental organizations[which?] vowed[clarification needed] to block any further development of the river, and a number of later dam and aqueduct proposals were defeated by citizen opposition. Sierra Club leader David Brower fought the dam both during the construction and for many years afterwards until his death in 2000. Brower believed that he was personally responsible for the failure to prevent Glen Canyon's flooding, calling it his "greatest mistake, greatest sin".[238][239]

In addition to Glen Canyon Dam, the CRSP includes the Flaming Gorge Dam on the Green River, the Blue Mesa, Morrow Point and Crystal Dams on the Gunnison River, and the Navajo Dam on the San Juan River. A total of 22 "participating projects" (of which 16 have been constructed) were later authorized in order to develop local water supplies at various locations across the Upper Basin states.[236] These include the Central Utah Project, which delivers 102,000 acre feet (126,000,000 m3) per year from the Green River basin to the Wasatch Front, and the San Juan–Chama Project, which diverts 110,000 acre feet (140,000,000 m3) per year from the San Juan River to the Rio Grande Valley. Both are multi-purpose projects serving a variety of agricultural, municipal and industrial uses.[240][241]

Pacific Southwest Water Plan

The main canal of the Central Arizona Project, crossing the Sonoran Desert

By the middle of the 20th century, planners were concerned that continued growth in water demand would outstrip the available water supply from the Colorado River. After exploring a multitude of potential projects, the USBR published a study in January 1964 known as the Pacific Southwest Water Plan, which proposed diverting water from the northwestern United States into the Colorado River basin.[242] Arizona's water allocation was a significant focus of the plan, due to the growing concern that its water supply could be curtailed due to California's seniority of water rights. In addition, the plan would guarantee full water supplies to Nevada, California and Mexico, allowing the Upper Basin states to utilize their full allocations without risking reductions in the Lower Basin.[242] The project would cost an estimated $3.1 billion.[243]

The first stage of this plan would divert water from Northern California's Trinity, Klamath and Eel Rivers to Southern California, allowing more Colorado River water to be used, by exchange, in Arizona. A canal system, which ultimately would become the Central Arizona Project (CAP), would be constructed to deliver Arizona's Colorado River allocation to Phoenix and Tucson, both located far away from the Colorado River in the middle of the state. At this point, central Arizona was still entirely dependent on local water supplies, such as the 1911 Theodore Roosevelt Dam,[244] and was quickly running out of surplus water.[242]

In order to supply the massive amount of power required to pump Colorado River water to central Arizona, two hydroelectric dams were proposed in the Grand Canyon (Bridge Canyon Dam and Marble Canyon Dam), which while not directly located in Grand Canyon National Park, would greatly impact flows of the Colorado River through the park.[242] With the controversy over Glen Canyon Dam still ongoing, the public pressure against these dams was immense.[243] As a result, the two Grand Canyon dams were omitted from the final CAP authorization in 1968.[245] In addition, the boundaries of Grand Canyon National Park were redrawn to prevent future dam projects in the area. The pumping power was replaced by the building of the coal-fired Navajo Generating Station near Page, Arizona, in 1976.[246][247][248] In 2019, the Navajo Generating Station ceased operation.[249]

The CAP was constructed in stages from 1973 to 1993, ultimately extending 336 miles (541 km) from the Colorado River at Parker Dam to Tucson, Arizona. It delivers 1.4 million acre feet (1.7 km3) of water per year, irrigates 830,000 acres (3,400 km2) of farmland and provides municipal water to about 5 million people.[246] Due to environmental concerns, most of the facilities proposed in the Pacific Southwest Water Plan were never built (though a smaller version of the Trinity River project was constructed as part of the unrelated Central Valley Project),[250] leaving Arizona and Nevada vulnerable to future water reductions under the Compact.[251]

Post-2000 water supply

When the Colorado River Compact was drafted in the 1920s, it was based on barely 30 years of streamflow records that suggested an average annual flow of 17.5 million acre feet (21.6 km3) past Lee's Ferry.[253] Modern studies of tree rings revealed that those three decades were probably the wettest in the past 500 to 1,200 years and that the natural long-term annual flow past Lee's Ferry is probably closer to 13.5 million acre feet (16.7 km3),[254][n 8] with a natural flow at the mouth around 16.3 million acre feet (20.1 km3).[3] This has resulted in more water being allocated to river users than actually exists in the Colorado.[256] Droughts have exacerbated the issue of water over-allocation.[257][258]

View of a reservoir where the water level has dropped, showing white deposits on the surrounding mountains
Lake Mead in 2010, showing the "bathtub ring" left behind by low water levels

The most severe drought on record, the southwestern North American megadrought, began in the early 21st century, in which the river basin has produced above-average runoff in only five years between 2000 and 2021.[259] The region is experiencing a warming trend, which is accompanied by earlier snowmelt, lower precipitation and greater evapotranspiration. A 2004 study showed that a 1–6 percent decrease of precipitation would lead to runoff declining by as much as 18 percent by 2050.[260]

Since 2000, reservoir levels have fluctuated greatly from year to year, but have experienced a steady long-term decline.[261] The particularly dry spell between 2000 and 2004 brought Lake Powell to just a third of capacity in 2005, the lowest level on record since initial filling in 1969.[262] In late 2010, Lake Mead was approaching the "drought trigger" elevation of 1,075 feet (328 m), at which water supplies to Arizona and Nevada would be reduced in accordance with the Colorado River Compact.[263] Due to Arizona and Nevada's water rights being junior to California's, their allocations can legally be cut to zero before any reductions are made on the California side.[256][264]

A wet winter in 2011 temporarily raised lake levels,[265][266] but dry conditions returned in the next two years.[267] In 2014, the Bureau of Reclamation cut releases from Lake Powell by 10 percent —the first such reduction since the 1960s, when Lake Powell was being filled for the first time.[268] This resulted in Lake Mead dropping to its lowest recorded level since 1937, when it was first being filled.[269]

Water year 2018 had a much lower-than-average snowpack.[270][271] In July 2021, after two more extremely dry winters, Lake Powell fell below the previous low set in 2005. In response, the Bureau of Reclamation began releasing water from upstream reservoirs in order to keep Powell above the minimum level for hydropower generation.[272][273] Lake Mead fell below the 1,075-foot (328 m) level expected to trigger federally mandated cuts to Arizona and Nevada's water supplies for the first time in history, and is expected to continue declining into 2022.[274]

On August 16, 2021, the Bureau of Reclamation released the Colorado River Basin August 2021 24-Month Study, and for the first time declared a shortage and that because of "ongoing historic drought and low runoff conditions in the Colorado River Basin, downstream releases from Glen Canyon Dam and Hoover Dam will be reduced in 2022 due to declining reservoir levels."[275] The Lower Basin reductions will reduce the annual apportionments – Arizona's by 18 percent, Nevada's by 7 percent, and Mexico's by 5 percent.[276]

On June 14, 2022, Bureau of Reclamation Commissioner Camille Touton told the Senate Committee on Energy and Natural resources that additional cuts of 2-4 million acre-feet were required to stabilize reservoir levels in 2023. Touton warned that if states were unable to negotiate the requisite cuts the Interior department may use its legal authority to cut releases.[277] When the states were unable to come to an agreement about how to share the proposed cuts, Reclamation began the legal steps to unilaterally reduce releases from Hoover and Glen Canyon Dams in 2023.[278] As of December 2022 the lower basin states of Nevada, Arizona, and California had not agreed on how to reduce water use by the approximately 30% required to keep levels in lakes Mead and Powell from crashing.[279] The Bureau of Reclamation has projected that water levels at Lake Powell could fall low enough that by July 2023 Glen Canyon Dam would no longer be able to generate any hydropower.[280] Arizona proposed a plan that severely cut allocations to California, and California responded with a plan that severely cut allocations to Arizona, failing to reach consensus. In April 2023, the federal government proposed cutting allocations to Nevada, Arizona, and California evenly which would cut deliveries by as much as one-quarter to each state, rather than according to senior water rights.[281]

In May 2023, the states finally reached a temporary agreement to prevent deadpool, reducing allocations by 3 million acre-feet over three years (until the end of 2026). 700,000 acre-feet were to be negotiated later among California, Arizona, and Nevada.[282] The cuts were less than the federal government had demanded, and so further cuts will be needed after 2026.[282] Fewer cuts were needed in the short term because the Colorado River Basin experienced an unusually rainy and snowy weather in early 2023.[282][283]

The agreement also became easier to negotiate because many cuts are being offset by one-time federal funding.[284] Billions of dollars in funding for programs in the Colorado River Basin to recycle water, increase efficiency, and competitive grants to pay water rights holders not to use water from the river are being provided by the Infrastructure Investment and Jobs Act and Inflation Reduction Act, and other programs funded through the United States Environmental Protection Agency and United States Department of the Interior. These are projected to reduce demand by hundreds of thousands of acre-feet per year.[285]

Ecology

Wildlife and plants

View of a wide river flowing through a forested area, with jagged mountains in the background
Heavily forested banks of the Colorado River near Topock, Arizona

The Colorado River and its tributaries often nourish extensive corridors of riparian growth as they traverse the arid desert regions of the watershed. Although riparian zones represent a relatively small proportion of the basin and have been affected by engineering projects and river diversion in many places, they have the greatest biodiversity of any habitat in the basin.[286] The most prominent riparian zones along the river occur along the lower Colorado below Davis Dam,[287] especially in the Colorado River Delta, where riparian areas support 358 species of birds despite the reduction in freshwater flow and invasive plants such as tamarisk (salt cedar).[288] Reduction of the delta's size has also threatened animals such as jaguars and the vaquita porpoise, which is endemic to the gulf.[289] Human development of the Colorado River has also helped to create new riparian zones by smoothing the river's seasonal flow, notably through the Grand Canyon.[290]

More than 1,600 species of plants grow in the Colorado River watershed, ranging from the creosote bush, saguaro cactus, and Joshua trees of the Sonoran and Mojave Deserts to the forests of the Rocky Mountains and other uplands, composed mainly of ponderosa pine, subalpine fir, Douglas-fir and Engelmann spruce.[60] Before logging in the 19th century, forests were abundant in high elevations as far south as the Mexico–U.S. border, and runoff from these areas nourished abundant grassland communities in river valleys. Some arid regions of the watershed, such as the upper Green River valley in Wyoming, Canyonlands National Park in Utah and the San Pedro River valley in Arizona and Sonora, supported extensive reaches of grassland roamed by large mammals such as buffalo and antelope as late as the 1860s. Near Tucson, Arizona, "where now there is only powder-dry desert, the grass once reached as high as the head of a man on horse back".[291]

Rivers and streams in the Colorado basin were once home to 49 species of native fish, of which 42 were endemic. Engineering projects and river regulation have led to the extinction of four species and severe declines in the populations of 40 species.[292] Bonytail chub, razorback sucker, Colorado pikeminnow, and humpback chub are among those considered the most at risk; all are unique to the Colorado River system and well adapted to the river's natural silty conditions and flow variations. Clear, cold water released by dams has significantly changed characteristics of habitat for these and other Colorado River basin fishes.[293] A further 40 species that occur in the river today, notably the brown trout, were introduced during the 19th and 20th centuries, mainly for sport fishing.[294]

Impacts of development

Most of the Colorado River basin water used by humans is used to grow feed for livestock—more than four times the amount used for crops for direct human consumption.[295]
View of a narrow green river flowing between high, reddish-brown cliffs
The Colorado was named for the reddish color caused by its natural sediment loads, but damming the river has caused it to acquire a clear green hue as seen here in lower Glen Canyon.

Historically, the Colorado transported from 85 to 100 million short tons (77,000,000 to 91,000,000 t) of sediment or silt to the Gulf of California each year – second only to the Mississippi among North American rivers.[296] This sediment nourished wetlands and riparian areas along the river's lower course, particularly in its 3,000-square-mile (7,800 km2) delta, once the largest desert estuary on the continent.[297] Currently, the majority of sediments carried by the Colorado River are deposited at the upper end of Lake Powell, and most of the remainder ends up in Lake Mead. Various estimates place the time it would take for Powell to completely fill with silt at 300 to 700 years. Dams trapping sediment not only pose damage to river habitat but also threaten future operations of the Colorado River reservoir system.[298]

Reduction in flow caused by dams, diversions, water for thermoelectric power stations,[299] and evaporation losses from reservoirs – the latter of which consumes more than 15 percent of the river's natural runoff[300]—has had severe ecological consequences in the Colorado River Delta and the Gulf of California. Historically, the delta with its large freshwater outflow and extensive salt marshes provided an important breeding ground for aquatic species in the Gulf. Today's desiccated delta, at only a fraction of its former size, no longer provides suitable habitat, and populations of fish, shrimp and sea mammals in the gulf have seen a dramatic decline.[195] Since 1963, the only times when the Colorado River has reached the ocean have been during El Niño events in the 1980s and 1990s.[301]

Reduced flows have led to increases in the concentration of certain substances in the lower river that have impacted water quality. Salinity is one of the major issues and also leads to the corrosion of pipelines in agricultural and urban areas.[302] The lower Colorado's salt content was about 50 parts per million (ppm) in its natural state,[195] but by the 1960s, it had increased to well over 2000 ppm.[303] By the early 1970s, there was also serious concern about salinity caused by salts leached from local soils by irrigation drainage water, which were estimated to add 10 million short tons (9,100,000 t) of excess salt to the river per year. The Colorado River Basin Salinity Control Act was passed in 1974, mandating conservation practices including the reduction of saline drainage. The program reduced the annual load by about 1.2 million short tons (1,100,000 t), but salinity remains an ongoing issue.[304] In 1997, the USBR estimated that saline irrigation water caused crop damages exceeding $500 million in the U.S. and $100 million in Mexico. Further efforts have been made to combat the salt issue in the lower Colorado, including the construction of a desalination plant at Yuma.[305] In 2011, the seven U.S. states agreed upon a "Plan of Implementation", which aims to reduce salinity by 644,000 short tons (584,000 t) per year by 2030.[304] In 2013, the Bureau of Reclamation estimated that around $32 million was spent each year to prevent around 1.2 million tons of salt from entering and damaging the Colorado River.[302]

Agricultural runoff containing pesticide residues has also been concentrated in the lower river in greater amounts. This has led to fish kills; six of these events were recorded between 1964 and 1968 alone.[306] The pesticide issue is even greater in streams and water bodies near agricultural lands irrigated by the Imperial Irrigation District with Colorado River water. In the Imperial Valley, Colorado River water used for irrigation overflows into the New and Alamo rivers and into the Salton Sea. Both rivers and the sea are among the most polluted bodies of water in the United States, posing dangers not only to aquatic life but to contact by humans and migrating birds.[307][308] Pollution from agricultural runoff is not limited to the lower river; the issue is also significant in upstream reaches such as Colorado's Grand Valley, also a major center of irrigated agriculture.[309]

Large dams such as Hoover and Glen Canyon typically release water from lower levels of their reservoirs, resulting in stable and relatively cold year-round temperatures in long reaches of the river. The Colorado's average temperature once ranged from 85 °F (29 °C) at the height of summer to near freezing in winter, but modern flows through the Grand Canyon, for example, rarely deviate significantly from 46 °F (8 °C).[310] Changes in temperature regime have caused declines of native fish populations, and stable flows have enabled increased vegetation growth, obstructing riverside habitat.[311] These flow patterns have also made the Colorado more dangerous to recreational boaters; people are more likely to die of hypothermia in the colder water, and the general lack of flooding allows rockslides to build up, making the river more difficult to navigate.[312]

Minute 319

In the 21st century, there has been renewed interest in restoring a limited water flow to the delta. In November 2012, the U.S. and Mexico reached an agreement, known as Minute 319, permitting Mexico storage of its water allotment in U.S. reservoirs during wet years, thus increasing the efficiency with which the water can be used. In addition to renovating irrigation canals in the Mexicali Valley to reduce leakage, this will make about 45,000 acre feet (56,000,000 m3) per year available for release to the delta on average. The water will be used to provide both an annual base flow and a spring "pulse flow" to mimic the river's original snowmelt-driven regime.[313][314] The first pulse flow, an eight-week release of 105,000 acre feet (130,000,000 m3), was initiated on March 21, 2014, with the aim of revitalising 2,350 acres (950 hectares) of wetland.[315] This pulse reached the sea on May 16, 2014, marking the first time in 16 years that any water from the Colorado flowed into the ocean, and was hailed as "an experiment of historic political and ecological significance" and a landmark in U.S.–Mexican cooperation in conservation.[11][316][317] The pulse will be followed by the steady release of 52,000 acre feet (64,000,000 m3) over the following three years, just a small fraction of its average flow before damming.[315][needs update]

Recreation

View of two small boats in a river, with high cliffs rising immediately behind them
A rafting party on the Colorado River

Famed for its dramatic rapids and canyons, the Colorado is one of the most desirable whitewater rivers in the United States, and its Grand Canyon section—run by more than 22,000 people annually[318]—has been called the "granddaddy of rafting trips".[319] Grand Canyon trips typically begin at Lee's Ferry and take out at Diamond Creek or Lake Mead; they range from one to eighteen days for commercial trips and from two to twenty-five days for private trips.[320] Private (noncommercial) trips are extremely difficult to arrange because the National Park Service limits river traffic for environmental purposes; people who desire such a trip often have to wait more than 10 years for the opportunity.[321]

Several other sections of the river and its tributaries are popular whitewater runs, and many of these are also served by commercial outfitters. The Colorado's Cataract Canyon and many reaches in the Colorado headwaters are even more heavily used than the Grand Canyon, and about 60,000 boaters run a single 4.5-mile (7.2 km) section above Radium, Colorado, each year.[322] The upper Colorado also includes many of the river's most challenging rapids, including those in Gore Canyon, which is considered so dangerous that "boating is not recommended".[322] Another section of the river above Moab, known as the Colorado "Daily" or "Fisher Towers Section", is the most visited whitewater run in Utah, with more than 77,000 visitors in 2011 alone.[323] The rapids of the Green River's Gray and Desolation Canyons[324] and the less difficult "Goosenecks" section of the lower San Juan River are also frequently traversed by boaters.[325]

Eleven U.S. national parks—Arches, Black Canyon of the Gunnison, Bryce Canyon, Canyonlands, Capitol Reef, Grand Canyon, Mesa Verde, Petrified Forest, Rocky Mountain, Saguaro, and Zion—are in the watershed, in addition to many national forests, state parks, and recreation areas.[326] Hiking, backpacking, camping, skiing, and fishing are among the multiple recreation opportunities offered by these areas. Fisheries have declined in many streams in the watershed, especially in the Rocky Mountains, because of polluted runoff from mining and agricultural activities.[327] The Colorado's major reservoirs are also heavily traveled summer destinations. Houseboating and water-skiing are popular activities on Lakes Mead, Powell, Havasu, and Mojave, as well as Flaming Gorge Reservoir in Utah and Wyoming, and Navajo Reservoir in New Mexico and Colorado. Lake Powell and surrounding Glen Canyon National Recreation Area received more than two million visitors per year in 2007,[328] while nearly 7.9 million people visited Lake Mead and the Lake Mead National Recreation Area in 2008.[329] Colorado River recreation employs some 250,000 people and contributes $26 billion each year to the Southwest economy.[330]

See also

  • Colorado River Delta
  • Colorado Desert
  • List of Colorado River rapids and features
  • List of dams in the Colorado River system
  • List of largest reservoirs in the United States
  • List of longest rivers of Mexico
  • List of longest rivers of the United States (by main stem)
  • London Bridge (Lake Havasu City)
  • Moab uranium mill tailings pile
  • Upper Colorado River Endangered Fish Recovery Program

Notes

  1. Discharge data is for Green River, Utah, 117.6 miles (189.3 km) upstream from the mouth. The stream gauge here measures flow from an area of 44,850 square miles (116,200 km2), representing about 93.2 percent of the basin.[43]
  2. Before large irrigation and municipal diversions, the Gila River discharged about 1.3 million acre feet (1.6 km3) per year,[40] which equals a flow of nearly 2,000 cubic feet per second (57 m3/s).
  3. Discharge data is for Bluff, Utah, located about 113.5 miles (182.7 km) above the confluence with the Colorado. The gauge measures flow from an area of 23,000 square miles (60,000 km2), about 93.5 percent of the basin.[46]
  4. Discharge data is for Littlefield, Arizona, about 66 miles (106 km) from the confluence with the Colorado, and also upstream of the confluence with its major tributary, the Muddy River. The gauge measures flow from an area of 5,090 square miles (13,200 km2), about 39.1 percent of the total basin.[53]
  5. NIB = "Northerly International Boundary", or the point at which the Colorado begins to form the Mexico–U.S. border, south of Yuma. Also note that the SIB ("Southerly International Boundary") is the point at which the Colorado ceases to form the border and passes entirely into Mexico.
  6. American population (9.7 million) calculated from statistics from the U.S. Census Bureau[93] and the State of Colorado.[94] The population in Mexico is about 3 million.[95]
  7. The average discharge of the Colorado (Grand) River at Cisco, Utah, about 97 miles (156 km) upstream from the Green River confluence, is 7,181 cubic feet per second (203.3 m3/s); between here and the confluence, only a few small, intermittent tributaries join the river.[74]The Green River has an average discharge of 6,048 cubic feet per second (171.3 m3/s) as measured at Green River, Utah, about 117.6 miles (189.3 km) above the confluence;[43] below here the only major tributary is the San Rafael River, which contributes an average of 131 cubic feet per second (3.7 m3/s), resulting in a total of 6,169 cubic feet per second (174.7 m3/s), still significantly lower than the discharge of the Colorado at their confluence.[193]
  8. The discrepancy between the natural flow at Lee's Ferry (13.5 million acre-feet or 16.65 km3) and the gauged flow between 1922 and 2020 (10.58 million acre-feet or 13.05 km3)[80] is mostly due to water diversions above Lee's Ferry and evaporation from reservoirs, especially Lake Powell.[255]

References

  1. 1.0 1.1 "Colorado River". United States Geological Survey. February 8, 1980. https://geonames.usgs.gov/apex/f?p=gnispq:3:::NO::P3_FID:45730. 
  2. 2.0 2.1 2.2 2.3 Kammerer, J.C. (May 1990). "Largest Rivers in the United States". U.S. Geological Survey. http://pubs.usgs.gov/of/1987/ofr87-242/. 
  3. 3.0 3.1 3.2 3.3 Nowak, Kenneth C. (April 2, 2012). "Stochastic Streamflow Simulation at Interdecadal Time Scales and Implications to Water Resources Management in the Colorado River Basin". Center for Advanced Decision Support for Water and Environmental Systems. University of Colorado. p. 114. http://cadswes.colorado.edu/sites/default/files/PDF/Theses-PhD/Nowak-PhD.pdf. 
  4. 4.0 4.1 "USGS Gage #09424000 on the Colorado River near Topock, AZ – Daily Data". National Water Information System. U.S. Geological Survey. February 14, 1935. http://nwis.waterdata.usgs.gov/nwis/dv?cb_00060=on&cb_80154=on&cb_80155=on&format=html&begin_date=1935-02-14&end_date=1935-02-14&site_no=09424000&referred_module=sw. 
  5. 5.0 5.1 Wiltshire, Gilbert & Rogers 2010, p. 102.
  6. "The Compact and Lees Ferry". Colorado River Streamflow: A Paleo Perspective. Western Water Assessment. http://wwa.colorado.edu/treeflow/lees/compact.html. 
  7. 7.0 7.1 Waterman, Jonathan (February 15, 2012). "Where the Colorado Runs Dry". The New York Times. https://www.nytimes.com/2012/02/15/opinion/where-the-colorado-river-runs-dry.html?_r=0. 
  8. 8.0 8.1 "Imperial Valley". Encyclopædia Britannica. 1995. 
  9. "San Juan – Chama Project". https://www.sanjuanchama.org/san-juan-chama-project-19511976. 
  10. "Precipitation Trends and Water Consumption in the Southwestern United States". Impact of Climate Change and Land Use in the Southwestern United States. U.S. Geological Survey. November 28, 2003. http://geochange.er.usgs.gov/sw/changes/natural/diaz/. 
  11. 11.0 11.1 Postel, Sandra (May 19, 2014). "A Sacred Reunion: The Colorado River Returns to the Sea". National Geographic. https://blog.nationalgeographic.org/2014/05/19/a-sacred-reunion-the-colorado-river-returns-to-the-sea/. Retrieved May 19, 2021. 
  12. "La Poudre Pass". United States Geological Survey. October 13, 1978. https://geonames.usgs.gov/apex/f?p=gnispq:3:::NO::P3_FID:177510. 
  13. Lindberg 2009, p. 38.
  14. Benke & Cushing 2005, p. 490.
  15. 15.0 15.1 "Longitudinal Trends in Channel Characteristics of the Colorado River and Implications for Food-Web Dynamics". University of Colorado. March 2000. http://www.colorado.edu/geography/geomorph/usfws_reports/USFWS00.pdf. 
  16. U.S. Geological Survey. "United States Geological Survey Topographic Maps: Fall River Pass, Colorado quad". TopoQuest. http://www.topoquest.com/map-detail.php?usgs_cell_id=14931. 
  17. U.S. Geological Survey. "United States Geological Survey Topographic Maps: Westwater, Utah quad". TopoQuest. http://www.topoquest.com/map-detail.php?usgs_cell_id=48474. 
  18. "Affected Environment". Remediation of the Moab Uranium Mill Tailings, Grand and San Juan Counties, Utah Final Environmental Impact Statement. Moab, Utah, UMTRA Project. p. 28. http://www.gjem.energy.gov/moab/documents/eis/final_eis/Volume_I/Chapter3.pdf. 
  19. "Guidebook to the Colorado River Part 3: Moab to Hite, Utah through Canyonlands National Park". Brigham Young University Geology Studies Volume 18 – Part 2. Brigham Young University. 1971. http://geology.byu.edu/drupal/sites/default/files/volume-18-part-2-1971.pdf. 
  20. Hopkins 2002, p. 118.
  21. Van Cott 1990, p. 70.
  22. Van Cott 1990, p. 155.
  23. "Rivers". Canyonlands National Park. U.S. National Park Service. June 17, 2011. http://www.nps.gov/cany/planyourvisit/rivers.htm. 
  24. "Lake Powell". Colorado River Storage Project. U.S. Bureau of Reclamation. November 4, 2008. http://www.usbr.gov/uc/rm/crsp/gc/lakepowell.html. 
  25. Rusho, W.L. (1992). "Lee's Ferry, Arizona". Utah History Encyclopedia. University of Utah. http://www.uen.org/utah_history_encyclopedia/l/LEES_FERRY.html. Retrieved February 19, 2012. 
  26. "Grand Canyon National Park, Arizona: Geology Fieldnotes". U.S. National Park Service. http://www.nature.nps.gov/geology/parks/grca/. 
  27. Leopold, Luna B.. "The Rapids and the Pools – Grand Canyon". Geological Survey Professional Paper 669–D. U.S. Geological Survey. p. 133. http://www.riversimulator.org/Resources/USGS/TheRapidsAndPoolsGrandCanyon.pdf. 
  28. 28.0 28.1 "Hoover Dam Frequently Asked Questions and Answers: Lake Mead". U.S. Bureau of Reclamation. December 2008. http://www.usbr.gov/lc/hooverdam/faqs/lakefaqs.html. 
  29. "Hoover Dam Bypass Is 2012 OCEA Winner; OPAL Lifetime Achievement Recipients Honored; Pankow, Michel Awards Presented". American Society of Civil Engineers. http://www.asce.org/OCEA-2012/. 
  30. "The Colorado River Indian Tribes Reservation (C.R.I.T.) Quick Facts". Arizona Cooperative Extension. University of Arizona. August 2010. http://www.indiancountryextension.org/sites/indiancountryextension.org/files/publications/files/u6/CRIT%20Quick%20Facts%20Oct08.pdf. 
  31. "Appendix J: Mainstem Impacts Analysis". Draft Environmental Impact Statement: Allocation of Water Supply and Long-Term Contract Execution, Central Arizona Project. U.S. Bureau of Reclamation. http://www.usbr.gov/lc/phoenix/reports/capdeis/Appendices/AppendixJ.pdf. 
  32. U.S. Geological Survey. "United States Geological Survey Topographic Maps: Blythe NE, California quad". TopoQuest. http://www.topoquest.com/map-detail.php?usgs_cell_id=4619. 
  33. Gupta 2007, p. 204.
  34. Alles, David L., ed (October 28, 2011). "The Lower Colorado River". Biology Department. Western Washington University. http://fire.biol.wwu.edu/trent/alles/LowerColorado.pdf. 
  35. "Fighting For Water in Arid Imperial Valley". National Public Radio. February 10, 2011. https://www.npr.org/2011/02/10/133624969/fighting-for-water-in-the-arid-imperial-valley. 
  36. "Border Water Source of Conflict and Cooperation: What Makes Management of Border Water Resources a Challenge?". Arroyo. University of Arizona. 2012. http://wrrc.arizona.edu/sites/wrrc.arizona.edu/files/Arroyo-2012.pdf. 
  37. Felger & Broyles 2007, pp. 519–520.
  38. "Executive Summary, Green River Basin Water Plan". Wyoming State Water Plan. February 2001. http://waterplan.state.wy.us/plan/green/execsumm.html. 
  39. 39.0 39.1 39.2 39.3 39.4 39.5 39.6 39.7 39.8 "Boundary Descriptions and Names of Regions, Subregions, Accounting Units and Cataloging Units". U.S. Geological Survey. http://water.usgs.gov/GIS/huc_name.html. 
  40. 40.0 40.1 Benke & Cushing 2005, p. 514.
  41. Benke & Cushing 2005, pp. 532–533.
  42. "Green River". Utah Rivers Council. http://www.utahrivers.org/programs/green-river/. 
  43. 43.0 43.1 43.2 "USGS Gage #09315000 on the Green River at Green River, UT". National Water Information System. U.S. Geological Survey. 1895–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09315000.2010.pdf. 
  44. "USGS Gage #09520000 on the Gila River near Dome, AZ". National Water Information System. U.S. Geological Survey. 1905–2011. http://wdr.water.usgs.gov/wy2011/pdfs/09520500.2011.pdf. 
  45. 45.0 45.1 The National Map . U.S. Geological Survey. Accessed February 25, 2012
  46. 46.0 46.1 "USGS Gage #09379000 on the San Juan River near Bluff, UT". National Water Information System. U.S. Geological Survey. 1914–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09379500.2010.pdf. 
  47. "Report, Findings, and Determination Regarding the Navigability of the Little Colorado River From its Headwaters to the Confluence with the Colorado River". Arizona Navigable Stream Adjudication Commission. 2005. http://www.azstreambeds.com/UserFiles/File/pdf/finalreports/Little%20Colorado%20River.pdf. 
  48. "USGS Gage #09402300 on the Little Colorado River Above the Mouth near Desert View, AZ". National Water Information System. U.S. Geological Survey. 1990–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09402300.2010.pdf. 
  49. Fielder 2002, p. 403.
  50. "USGS Gage #09180000 on the Dolores River near Cisco, UT". National Water Information System. U.S. Geological Survey. 1950–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09180000.2010.pdf. 
  51. "USGS Gage #09152000 on the Gunnison River near Grand Junction, CO". National Water Information System. U.S. Geological Survey. 1897–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09152500.2010.pdf. 
  52. Annerino 1999, p. 8.
  53. 53.0 53.1 "USGS Gage #09415000 on the Virgin River at Littlefield, AZ". National Water Information System. U.S. Geological Survey. 1929–2010. http://wdr.water.usgs.gov/wy2010/pdfs/09415000.2010.pdf. 
  54. 54.0 54.1 Wiltshire, Gilbert & Rogers 2010, pp. 101–102.
  55. Leopold 1994, p. 267.
  56. Committee to Review the Glen Canyon Environmental Studies 1996, p. 51.
  57. "USGS Gage #09421500 on the Colorado River below Hoover Dam". National Water Information System. U.S. Geological Survey. 1934–2011. http://nwis.waterdata.usgs.gov/nwis/monthly/?referred_module=sw&site_no=09421500&por_09421500_15=172091,00060,15,1934-04,2011-09&format=html_table&date_format=YYYY-MM-DD&rdb_compression=file&submitted_form=parameter_selection_list. 
  58. 58.0 58.1 58.2 58.3 "Climatic Fluctuations, Drought, and Flow in the Colorado River Basin". USGS Fact Sheet 2004-3062. U.S. Geological Survey. August 2004. http://pubs.usgs.gov/fs/2004/3062/. 
  59. "For A Few Weeks The Colorado River Reached The Ocean. Will It Happen Again?". 2018-02-19. https://www.kpbs.org/news/midday-edition/2018/02/19/few-weeks-colorado-river-reached-ocean-will-it-hap. 
  60. 60.0 60.1 Benke & Cushing 2005, p. 488.
  61. Preston, Ben (March 22, 2010). "The Risky Business of Slicing the Pie". Miller–McCune. https://psmag.com/environment/the-risky-business-of-slicing-the-pie-11068. 
  62. "Runoff in the Upper Colorado River Basin Water Years, 1983–85, and Comparisons with Forecasts of Runoff to Lake Powell". Western Snow Conference. http://www.westernsnowconference.org/proceedings/pdf_Proceedings/1987%20WEB/WahlUpperColoradoRiverBasinForecastsOfRunoff.pdf. 
  63. Cohen, Michael J.; Henges-Jeck, Christine; Castillo-Moreno, Gerardo (2001). "A Preliminary Water Balance for the Colorado River Delta, 1992–1998". Journal of Arid Environments 49 (1): 35–48. doi:10.1006/jare.2001.0834. Bibcode2001JArEn..49...35C. http://www.pacinst.org/wp-content/uploads/2013/02/missing_water_article_web3.pdf. Retrieved June 27, 2013. 
  64. Zimmerman, Janet (October 6, 2010). "Colorado River Drought Threatens Power Production". The Press-Enterprise (Riverside, California). http://www.pe.com/local-news/topics/topics-environment-headlines/20101006-region-colorado-river-drought-threatens-power-production.ece. 
  65. Stark, Mike (April 21, 2009). "Study: Shortages Likely on Colorado River by 2050". USA Today. Associated Press. http://usatoday30.usatoday.com/weather/drought/2009-04-21-colorado-river-shortages_N.htm. 
  66. "Past Peak Water in the Southwest". Western Water Assessment. http://wwa.colorado.edu/climate_change/docs/hoerling%20past%20peak%20water%20in%20press.pdf. 
  67. McKinnon, Shaun (August 9, 2006). "Mines, Farms Put Gila River on Life Support: Despite Lack of Regulation, Some Trying to Restore River to Its Natural Beauty and Wonder". Arizona Republic. http://www.azcentral.com/specials/special06/articles/0809rivers0809NEW.html. 
  68. 68.0 68.1 "Water-Year Summary for Site USGS 09522000 Colorado River at Northerly International Boundary, above Morelos Dam, near Andrade, CA". National Water Information System. U.S. Geological Survey. 1950–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=5815&wys_water_yr=2020&site_no=09522000&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  69. "Reclamation". Colorado River Water Users Association. http://www.crwua.org/colorado-river/uses/reclamation. 
  70. Christensen, Niklas S.; Wood, Andrew W.; Voisin, Nathalie; Lettenmaier, Dennis P.; Palmer, Richard N. (2004). "The Effects of Climate Change on the Hydrology and Water Resources of the Colorado River Basin". Climatic Change 62 (337–363): 345. doi:10.1023/b:clim.0000013684.13621.1f. https://portal.azoah.com/oedf/documents/08A-AWS001-DWR/Supplemental_Beverly_et_al/20040000%20Christensen%20et%20al%20Effects%20of%20Climate%20Change%20on%20Hydrology%20and%20Water%20Resources_Colorado%20River%20B.pdf. Retrieved July 13, 2013. 
  71. "USGS Gage #09522200 on the Colorado River at NIB, Above Morelos Dam, AZ – Annual Statistics". National Water Information System. U.S. Geological Survey. 1951–1992. http://nwis.waterdata.usgs.gov/nwis/monthly/?referred_module=sw&site_no=09522200&por_09522200_1=19984,00060,1,1960-10,1986-09&format=html_table&date_format=YYYY-MM-DD&rdb_compression=file&submitted_form=parameter_selection_list. 
  72. "Water-Year Summary for Site USGS 09010500 Colorado River below Baker Gulch near Grand Lake, CO". National Water Information System. U.S. Geological Survey. 1953–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=18363&wys_water_yr=2020&site_no=09010500&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  73. "Water-Year Summary for Site USGS 09070500 Colorado River near Dotsero, CO". National Water Information System. U.S. Geological Survey. 1941–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=18624&wys_water_yr=2020&site_no=09070500&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  74. 74.0 74.1 "Water-Year Summary for Site USGS 09180500 Colorado River near Cisco, UT". National Water Information System. U.S. Geological Survey. 1914–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=142741&wys_water_yr=2020&site_no=09180500&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  75. 75.0 75.1 75.2 "Water-Year Summary for Site USGS 09380000 Colorado River at Lees Ferry, AZ". National Water Information System. U.S. Geological Survey. 1922–2020. https://nwis.waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=236239&wys_water_yr=2020&site_no=09380000&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019&referred_module=. 
  76. "Water-Year Summary for Site USGS 09423000 Colorado River below Davis Dam, AZ–NV". National Water Information System. U.S. Geological Survey. 1905–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=5378_5379_5380&wys_water_yr=2020&site_no=09423000&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  77. "Water-Year Summary for Site USGS 09427520 Colorado River below Parker Dam, AZ–CA". National Water Information System. U.S. Geological Survey. 1935–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=5403&wys_water_yr=2020&site_no=09427520&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  78. "Water-Year Summary for Site USGS 09429600 Colorado River below Laguna Dam, AZ–CA". National Water Information System. U.S. Geological Survey. 1972–2020. https://waterdata.usgs.gov/nwis/wys_rpt?dv_ts_ids=5438&wys_water_yr=2020&site_no=09429600&agency_cd=USGS&adr_water_years=2006%2C2007%2C2008%2C2009%2C2010%2C2011%2C2012%2C2013%2C2014%2C2015%2C2016%2C2017%2C2018%2C2019%2C2020&referred_module=. 
  79. "USGS Surface-Water Annual Statistics for USA Grouped by Hydrologic Unit". National Water Information System. U.S. Geological Survey. http://waterdata.usgs.gov/nwis/annual?referred_module=sw&search_station_nm=colorado%20river&search_station_nm_match_type=beginning&site_tp_cd=OC&site_tp_cd=OC-CO&site_tp_cd=ES&site_tp_cd=LK&site_tp_cd=ST&site_tp_cd=ST-CA&site_tp_cd=ST-DCH&site_tp_cd=ST-TS&format=station_list&sort_key=site_no&group_key=NONE&list_of_search_criteria=search_station_nm%2Csite_tp_cd%2Crealtime_parameter_selection. 
  80. 80.0 80.1 "USGS Gage #09380000 on the Colorado River at Lee's Ferry, AZ". National Water Information System. U.S. Geological Survey. 1921–2010. http://nwis.waterdata.usgs.gov/nwis/monthly/?referred_module=sw&site_no=09380000&por_09380000_1=19133,00060,1,1921-10,2011-09&format=html_table&date_format=YYYY-MM-DD&rdb_compression=file&submitted_form=parameter_selection_list. 
  81. 81.0 81.1 81.2 Benke & Cushing 2005, pp. 483–486.
  82. 82.0 82.1 82.2 82.3 "Watersheds (map)". Commission for Environmental Cooperation. 2006. http://www.cec.org/naatlas/img/NA-Watersheds.gif. 
  83. 83.0 83.1 83.2 83.3 "Current Understanding of Colorado River Basin Climate and Hydrology". Western Water Assessment. April 2020. https://wwa.colorado.edu/sites/default/files/2021-06/ColoRiver_StateOfScience_WWA_2020_Chapter_2.pdf. Retrieved May 24, 2022. 
  84. "River Basins of Mexico". University of Texas. 1975. http://www.lib.utexas.edu/maps/atlas_mexico/river_basins.jpg. 
  85. Fassnacht, S.R. (2004). "Streamflow Predictability in the Upper Versus Lower Colorado River Sub-Basins". Eastern Snow Conference. http://www.easternsnow.org/proceedings/2004/fassnacht2.pdf. 
  86. "Lees Ferry (historical)". United States Geological Survey. February 8, 1980. https://geonames.usgs.gov/apex/f?p=gnispq:3:::NO::P3_FID:6959. 
  87. "Annual Report on the Salton Sea Management Program". California Natural Resources Agency. March 2021. https://saltonsea.ca.gov/wp-content/uploads/2021/03/2021-Annual-Report_3-5-21.pdf. Retrieved May 26, 2022. 
  88. 88.0 88.1 88.2 88.3 Singh, Ramesh K.; Senay, Gabriel B.; Velpuri, Naga Manohar; Kagone, Stephanie (January 2014). "Actual Evapotranspiration (Water Use) Assessment of the Colorado River Basin at the Landsat Resolution Using the Operational Simplified Surface Energy Balance Model". Remote Sensing 6 (1): 233–256. doi:10.3390/rs6010233. https://www.researchgate.net/publication/259481061. 
  89. Benke & Cushing 2005, pp. 483–489.
  90. "Contributions of Watershed Management Research to Ecosystem-Based Management in the Colorado River Basin". USDA Forest Service Proceedings RMRS–P–13. U.S. Forest Service. 2000. http://www.fs.fed.us/rm/pubs/rmrs_p013/rmrs_p013_117_128.pdf. 
  91. Climate and Hydrology of the Colorado River Basin Region. National Academies Press. 2007. doi:10.17226/11857. ISBN 978-0-309-10524-8. https://nap.nationalacademies.org/read/11857/chapter/5. Retrieved May 23, 2022. 
  92. Features and Dynamics of Colorado River Basin Climate. National Academies Press. 2007. doi:10.17226/11857. ISBN 978-0-309-10524-8. http://www.nap.edu/openbook.php?record_id=11857&page=76. Retrieved February 19, 2012. 
  93. "State and County QuickFacts". U.S. Census Bureau. http://quickfacts.census.gov/qfd/index.html. 
  94. "Population and Demographics" (PDF). Colorado Data Book. State of Colorado. September 2007. http://www.colorado.gov/cs/Satellite?blobcol=urldata&blobheader=application%2Fpdf&blobheadername1=Content-Disposition&blobheadername2=MDT-Type&blobheadervalue1=inline%3B+filename%3D555%2F20%2FDB2007-Pop.pdf&blobheadervalue2=abinary%3B+charset%3DUTF-8&blobkey=id&blobtable=MungoBlobs&blobwhere=1191378405012&ssbinary=true. 
  95. "Colorado River Basin Salinity Control Program". Natural Resources Conservation Service. U.S. Department of Agriculture. July 12, 2010. https://www.nrcs.usda.gov/wps/portal/nrcs/detail/national/programs/alphabetical/?&cid=stelprdb1044198. 
  96. "Colorado River Basin Water Management: Evaluating and Adjusting to Hydroclimatic Variability (Report in Brief)". Division on Earth & Life Studies. National Academies. February 2007. http://dels.nas.edu/resources/static-assets/materials-based-on-reports/reports-in-brief/colorado_river_management_final.pdf. 
  97. Prisciantelli 2002, p. 56.
  98. Cannon, Eric (April 28, 2002). "The Mid-Tertiary Ignimbrite Flare-Up". University of Colorado, Boulder. http://www.colorado.edu/GeolSci/Resources/WUSTectonics/CzIgnimbrite/ignimbrite_intro.html. 
  99. Foos, Annabelle. "Geology of the Colorado Plateau". U.S. National Park Service. http://www.nature.nps.gov/geology/education/foos/plateau.pdf. 
  100. Martin-Barajas, Arturo (July 2009). "The Tectonic Evolution of the Gulf of California". Division of Geological and Planetary Sciences. California Institute of Technology. http://www.gps.caltech.edu/~jstock/Bajares.html. 
  101. Young & Spamer 2001, p. 193.
  102. Davis, Jim (January 2009). "Why Does a River Run Through It?". Survey Notes (Utah Geological Survey) 41 (1). http://geology.utah.gov/surveynotes/gladasked/gladriver.htm. Retrieved February 19, 2012. 
  103. Prisciantelli 2002, p. 62.
  104. Alles, David L., ed (October 28, 2011). "Geology of the Salton Trough". Western Washington University. http://fire.biol.wwu.edu/trent/alles/GeologySaltonTrough.pdf. 
  105. "Reconstruction of Prehistoric Shorelines for Cultural Restraints using GIS". Salton Sea Database Program. ESRI. http://proceedings.esri.com/library/userconf/proc00/professional/papers/PAP751/p751.htm. 
  106. "A Fresh Look at Western Grand Canyon Lava Dams: Introduction". Grand Canyon River Guides. http://www.gcrg.org/bqr/16-4/dams.html. 
  107. "Evidence for Rapid Formation and Failure of Pleistocene "Lava Dams" of the Western Grand Canyon, Arizona". Institute for Creation Research. August 1998. http://static.icr.org/i/pdf/technical/Lava-Dams-of-the-Western-Grand-Canyon-Arizona.pdf. 
  108. Fenton, Cassandra R. et al. (2004). "Geochemical Discrimination of Five Pleistocene Lava-Dam Outburst-Flood Deposits, Western Grand Canyon, Arizona". Journal of Geology 112 (1): 91–110. doi:10.1086/379694. Bibcode2004JG....112...91F. http://www.ees.rochester.edu/RareGasLab/Fenton_etal_JGeology.pdf. Retrieved February 19, 2012. 
  109. Fenton, Cassandra R.; Webb, Robert H; Cerling, Thure E. (May 6, 2005). "Peak Discharge of a Pleistocene Lava-Dam Outburst Flood in Grand Canyon, Arizona, USA". Quaternary Research (U.S. Geological Survey) 65 (2): 324. doi:10.1016/j.yqres.2005.09.006. Bibcode2006QuRes..65..324F. http://wwwpaztcn.wr.usgs.gov/webb_pdf/Fenton-ea-2005-QR.pdf. Retrieved February 19, 2012. 
  110. 110.0 110.1 110.2 110.3 "People of the Colorado Plateau". Land Use History of North America. Northern Arizona University. http://cpluhna.nau.edu/People/people.htm. 
  111. "Formative Era/Fremont Culture". U.S. Bureau of Land Management. August 31, 2009. http://www.blm.gov/co/st/en/fo/wrfo/Cultural_Resources/formative_era_fremont.html. 
  112. "Fremont Culture". Dinosaur National Monument. U.S. National Park Service. http://www.nps.gov/dino/historyculture/fremont-culture.htm. 
  113. Vess, Deborah. "The Anasazi". Georgia College and State University. http://www.faculty.de.gcsu.edu/~dvess/ids/amtours/anawciv.htm. 
  114. "Water Development, Extraction, and Diversion". Land Use History of North America: Colorado Plateau. Northern Arizona University. p. 2. http://cpluhna.nau.edu/Change/waterdevelopment2.htm. 
  115. Fisher, Richard D.. "Ancient Knowledge of the Chaco Canyon Anasazi". Grand Canyons of the Earth. http://www.canyonsworldwide.com/chaco/images/ChacoCanyonAnasaziPaper.pdf. 
  116. "History & Culture". Chaco Culture National Historic Park. U.S. National Park Service. http://www.nps.gov/chcu/historyculture/index.htm. 
  117. "Pueblo Bonito". Evaluating Models of Chaco: A Virtual Conference. University of Colorado Boulder. http://www.colorado.edu/Conferences/chaco/tour/bonito.htm. 
  118. 118.0 118.1 Howard, Jerry B.. "Hohokam Legacy: Desert Canals". http://www.waterhistory.org/histories/hohokam2/. 
  119. Nobles 1998, p. 26.
  120. Logan 2006, pp. 21–22.
  121. 121.0 121.1 "Ancient Forest Management in the Chaco Canyon – From 600 AD to 1300 AD". Tenthmil. http://tenthmil.com/mission/timeline/ancient_forest_management_in_the_chaco_canyon. 
  122. Schwinning, Susan; Belnap, Jayne; Bowling, David R.; Ehleringer, James R. (2008). "Sensitivity of the Colorado Plateau to Change: Climate, Ecosystems and Society". Ecology and Society 13 (2): 28. doi:10.5751/ES-02412-130228. 
  123. "Desert Farmers at the River's Edge: The Hohokam and Pueblo Grande". Pueblo Grande Museum Archaeological Park. City of Phoenix. http://phoenix.gov/recreation/arts/museums/pueblo/about/visitorinfo/materials/dfdisappearance.html. 
  124. Hopi Dictionary/Hopìikwa Lavàytutuveni:. Hopi-English Dictionary of the Third Mesa Dialect. The Hopi Dictionary Project. Tucson: University of Arizona Press, 1997.
  125. Antone, Caroline. Piipayk m'iim. Salt River: Oʼodham Piipaash Language Program, 2000.
  126. Gupta 2010, p. 362.
  127. Hinton, Leanne (1984). A Dictionary of the Havasupai Language. Supai, Arizona: Havasupai Tribe. OCLC 12358778. 
  128. William Alan Shaterian (1983). Phonology and Dictionary of Yavapai (PhD dissertation). University of California, Berkeley. OCLC 13197420.
  129. 129.0 129.1 "Dine History and Facts". University of California, Irvine: Donald Bren School of Information and Computer Sciences. http://www.ics.uci.edu/~aisi/97_aisics/people/jsells/assign5.html. 
  130. "The Navajo: A Brief History". The Navajo Nation Division of Economic Development. http://www.navajobusiness.com/pdf/FstFctspdf/A%20Brief%20History.pdf. 
  131. "California: Mohave". Southwest Indian Relief Council. http://www.nrcprograms.org/site/PageServer?pagename=swirc_res_ca_mohave. 
  132. "Ute". Land Use History of North America. Northern Arizona University. http://cpluhna.nau.edu/People/ute_indians.htm. 
  133. 133.0 133.1 Benke & Cushing 2005, p. 486.
  134. 134.0 134.1 Shaw, Anne Moore. "A Pima Past". Salt River Pima-Maricopa Indian Community. http://www.srpmic-nsn.gov/history_culture/pimapast.asp. 
  135. Pritzker 1998, p. 309.
  136. "Navajo Nation". Indian Health Service. http://www.ihs.gov/navajo/index.cfm?module=nao_navajo_nation. 
  137. "Treaty Between the United States of America and the Navajo Tribe of Indians". Historic Documents. New Mexico State University. 1868. http://reta.nmsu.edu/modules/longwalk/lesson/document/treaty.htm. 
  138. "Navajo Nation – Facts at a Glance". The Navajo Nation. 2004. http://www.navajobusiness.com/fastFacts/Overview.htm. 
  139. Kessel & Wooster 2005, p. 217.
  140. "Fort Mojave Reservation". Tribal Library Census and Needs Assessment. California State University San Marcos. June 12, 2001. http://public.csusm.edu/loc/rezinfo/ftmojave/index.htm. 
  141. 141.0 141.1 "About the Mohave, Chemehuevi, Hopi and Navajo Tribes". Colorado River Indian Tribes. 2009. http://www.crit-nsn.gov/crit_contents/about/. 
  142. "The Colorado River Indian Tribes (C.R.I.T.) Reservation and Extension Programs". University of Arizona College of Agriculture and Life Sciences. Indian Country Extension. October 2008. http://www.indiancountryextension.org/sites/indiancountryextension.org/files/publications/files/u6/CRIT%20and%20Extension%20Programs.pdf. 
  143. "Ten Tribes Partnership". Colorado River Water Resources Association. http://www.crwua.org/colorado-river/ten-tribes. 
  144. Voggesser, Garrit (2001). "The Indian Projects". Bureau of Reclamation History Program. U.S. Bureau of Reclamation. http://www.usbr.gov/history/ProjectHistories/INDIAN%20PROJECTS%20OVERVIEW.pdf. 
  145. "Navajo Indian Irrigation Project". U.S. Bureau of Reclamation. May 11, 2011. http://www.usbr.gov/projects/Project.jsp?proj_Name=Navajo%20Indian%20Irrigation%20Project. 
  146. Jenkins, Matt (February 21, 2011). "In Navajoland, a Contentious Water Deal Divides the Tribe". High Country News (Paonia, Colorado). http://www.hcn.org/issues/43.3/in-navajoland-a-contentious-water-deal-divides-the-tribe. 
  147. "John Wesley Powell's Exploration of the Colorado River". U.S. Geological Survey. March 28, 2006. http://www.cr.nps.gov/history/online_books/geology/publications/inf/powell/sec2.htm. 
  148. Axelrod & Phillips 2008, p. 4.
  149. Lankford 2010, pp. 100–101.
  150. "Diaz, Melchior". New Mexico Office of the State Historian. http://www.newmexicohistory.org/filedetails.php?fileID=472. 
  151. Bolton 2017, pp. 440.
  152. Gudde & Bright 2004, p. 50.
  153. Dellenbaugh 1909, p. 60.
  154. Rolle 1999, p. 54.
  155. United States Army (August 11, 2005). Report of the secretary of war, communicating ... a reconnoissance of the gulf of California and the Colorado river by Lieutenant Derby .... http://name.umdl.umich.edu/aaw7868.0001.001. 
  156. 156.0 156.1 156.2 156.3 156.4 156.5 156.6 Richard E. Lingenfelter (1978). Steamboats on the Colorado River, 1852–1916. Tucson: University of Arizona Press. http://www.ansac.az.gov/UserFiles/PDF/08182014/X028_FMIBurtellLingenfelterSteamboats/FMI%20Lingenfelter%20Steamboats/Steamboats%20on%20the%20Colorado%20River%201852-1916.pdf. 
  157. "Overland Monthly and Out West Magazine". A. Roman and Company. August 11, 1895. https://books.google.com/books?id=7I8xAQAAMAAJ&pg=PA14. 
  158. Senate, United States Congress (August 11, 1854). Senate Documents, Otherwise Publ. as Public Documents and Executive Documents: 14th Congress, 1st Session-48th Congress, 2nd Session and Special Session. https://books.google.com/books?id=-4YFAAAAQAAJ&pg=PA93. 
  159. Byrd H. Granger (1960). Arizona Place Names. University of Arizona Press. p. 21. https://archive.org/details/arizonaplacename00barn. Retrieved December 9, 2011. 
  160. "Report of an expedition down the Zuni and Colorado Rivers". Washington, B. Tucker, Senate Print.. August 11, 1854. http://archive.org/details/reportanexpidit00sitggoog. 
  161. United States War Dept (August 11, 2005). Reports of explorations and surveys, to ascertain the most practicable and economical route for a railroad from the Mississippi River to the Pacific Ocean. http://name.umdl.umich.edu/afk4383.0003.001. 
  162. "Autobiography and Reminiscence of George Alonzo Johnson, San Diego, 1901.". https://oac.cdlib.org/ark:/13030/kt7p30228k/?order=2&brand=calisphere. 
  163. Ives, Joseph C. (August 11, 1861). "Report Upon the Colorado River of the West". U.S. Government Printing Office. https://books.google.com/books?id=1xIOAAAAQAAJ. 
  164. Dellenbaugh 1909, p. 170.
  165. Schmidt 1993, p. 12.
  166. Dolnick 2002, p. 5.
  167. Leuchtenburg 2000, p. 360.
  168. 168.0 168.1 Dolnick 2002, p. 238.
  169. "Three leave Powell's Grand Canyon expedition". This Day in History. History.com. http://www.history.com/this-day-in-history/three-leave-powells-grand-canyon-expedition. 
  170. "Historic 3D Photographs of the Second Powell Expedition (1871–1872)". Geology of National Parks. U.S. Geological Survey. February 13, 2012. http://3dparks.wr.usgs.gov/3Dcanyons/html/glencanyon.htm. 
  171. Warburton, David L. (May 16, 2005). "Geology of National Parks: Glen Canyon National Recreation Area". Florida Atlantic University. http://www.geosciences.fau.edu/Resources/CourseWebPages/Fall2011/GLY3165_F11/NPGLNCYNNRA_web.htm. 
  172. Peterson, Richard H. (1979). "Book Review: Steamboats on the Colorado River: 1852–1916". San Diego Historical Society Quarterly. San Diego History Center. http://www.sandiegohistory.org/journal/79fall/br-steamboats.htm. 
  173. Wildfang 2005, pp. 21–31.
  174. Cox, Christopher R. (July 2009). "True Nature: Surf's Up". Audubon Magazine. http://archive.audubonmagazine.org/truenature/truenature0709.html. 
  175. Kjerfve, Björn; Ferreria, Hélder O. (April 1993). "Tidal bores: First ever measurements". Ciéncia y Cultura (Journal of the Brazilian Association for the Advancement of Science) (Texas A&M University) 45 (2): pp. 135–137. http://geotest.tamu.edu/userfiles/167/126.pdf. 
  176. Lingenfelter 1978, pp. 9–13.
  177. 177.0 177.1 Williams, O.A. (1937). "Settlement and Growth of the Gila Valley as a Mormon Colony, 1879–1900". University of Arizona. http://uair.arizona.edu/system/files/usain/download/azu_e9791_1937_67_w.pdf. 
  178. Glass & Glass 1983, pp. 162–163.
  179. 179.0 179.1 "Lees Ferry History". Glen Canyon National Recreational Area. U.S. National Park Service. August 11, 2006. http://www.nps.gov/glca/historyculture/leesferryhistory.htm. 
  180. "Lees Ferry". Arizona State University. July 8, 2010. http://grandcanyonhistory.clas.asu.edu/sites_coloradorivercorridor_leesferry.html. 
  181. Brown 1972, pp. 52–53.
  182. Casey 2007, p. 251.
  183. Lindberg 2009, pp. 134–135.
  184. Kirkemo, Harold (May 21, 2007). "Prospecting for Gold in the United States". General Interest Publications. U.S. Geological Survey. http://pubs.usgs.gov/gip/prospect2/prospectgip.html. 
  185. "What Affects Water Quality in the Upper Colorado River Basin?". National Water-Quality Assessment, Upper Colorado River Basin Fact Sheet FS–109–96. U.S. Geological Survey. April 1996. http://pubs.usgs.gov/fs/fs-109-96/pdf/fs109-96.pdf. 
  186. Dwyer, John J. The Agrarian Dispute: The Expropriation of American-Owned Rural Land in Postrevolutionary Mexico. Durham: Duke University Press 2008
  187. Kerig, Dorothy P. "Yankee Enclave: The Colorado River Land Company and Mexican Agrarian Reform in Baja California, 1902-1944." PhD diss. University of California, Irvine 1988.
  188. Castillo-Muñoz, Verónica. The Other California: Land, Identities, and Politics on the Mexican Borderlands. Oakland: University of California Press 2017.
  189. 189.0 189.1 "Renaming the Grand River, Colo.", Hearing Before the Committee on Interstate and Foreign Commerce of the House of Representatives, Sixty Sixth Congress, Third Session, on HJ 460 (Government Printing Office), February 18, 1921, http://www.riversimulator.org/Resources/LawOfTheRiver/HearingToRenameGrandRiverColorado1921.pdf, retrieved May 16, 2023 
  190. Colorado River Water Conservation District (December 23, 2003). "Many Years Ago, the Colorado River Was Just Grand". SummitDaily. http://www.summitdaily.com/article/20031223/OPINION/312230302. 
  191. "House Joint Resolution 32 - To change the name of the Grand River in Colorado and Utah to the Colorado River". Congressional Record. Sixty-seventh United States Congress. July 25, 1921. p. 4274. https://www.govinfo.gov/content/pkg/GPO-CRECB-1921-pt5-v61/pdf/GPO-CRECB-1921-pt5-v61.pdf. 
  192. Barnes 1988, p. 104.
  193. "USGS Gage #09328500 on the San Rafael River near Green River, Utah". National Water Information System. U.S. Geological Survey. 1910–2012. http://wdr.water.usgs.gov/wy2012/pdfs/09328500.2012.pdf. 
  194. 194.0 194.1 "Colorado River Basin Water Supply and Demand Study". U.S. Bureau of Reclamation. December 2012. https://www.usbr.gov/watersmart/bsp/docs/finalreport/ColoradoRiver/CRBS_Executive_Summary_FINAL.pdf. Retrieved May 18, 2022. 
  195. 195.0 195.1 195.2 Davis, Eric F.. "The Colorado River Controversy" (PDF). Michigan State University. https://www.msu.edu/~davise16/pdf/The%20Colorado%20River%20Controversy.pdf?q=colorado-river. 
  196. "Low Water May Halt Hoover Dam's Power". Circle of Blue. September 22, 2010. http://www.circleofblue.org/waternews/2010/world/low-water-may-still-hoover-dam%E2%80%99s-power/. 
  197. "Hydropower". Glen Canyon Dam Adaptive Management Program. November 18, 2010. http://www.gcdamp.gov/keyresc/hydropower.html. 
  198. Waterman, Jonathan (August 11, 2010). "Restoring floods to America's Nile". National Geographic. http://newswatch.nationalgeographic.com/2010/08/11/restoring_floods_to_grand_caynon_river/. 
  199. Nabhan, Gary Paul (January 16, 2007). "The Beginning and the End of the Colorado River: Protecting the Sources, Ensuring its Courses". Northern Arizona University. http://www.environment.nau.edu/water/ColoradoRiver.htm. 
  200. Reisner 1993, p. 120.
  201. "Colorado River Law". Southern Nevada Water Authority. http://www.snwa.com/ws/river_law.html. 
  202. 202.0 202.1 "Colorado River Compact, 1922". U.S. Bureau of Reclamation. http://www.usbr.gov/lc/region/pao/pdfiles/crcompct.pdf. 
  203. 203.0 203.1 "Utilization of Waters of the Colorado and Tijuana Rivers and of the Rio Grande: Treaty Between the United States of America and Mexico". International Boundary and Water Commission. February 3, 1944. http://www.ibwc.gov/Files/1944Treaty.pdf. 
  204. "Colorado River". GOOD Magazine. http://awesome.good.is.s3.amazonaws.com/transparency/web/1009/colorado-river-2/flat.html. 
  205. "Big changes are coming for the Colorado River soon—and they could get messy" (in en). 2022-08-15. https://www.nationalgeographic.com/environment/article/big-changes-are-coming-for-the-colorado-river-soonand-they-could-get-messy. 
  206. 206.0 206.1 Anderson, Larry (May 2002). "Utah's Perspective: The Colorado River". Utah Division of Water Resources. http://www.water.utah.gov/interstate/thecoloradoriverart.pdf. 
  207. "The Law of the River". U.S. Bureau of Reclamation. March 2008. http://www.usbr.gov/lc/region/g1000/lawofrvr.html. 
  208. "Dams Along the Lower Colorado River". U.S. Bureau of Reclamation. https://www.usbr.gov/lc/yuma/facilities/dams/yao_dams_map.html. Retrieved May 18, 2022. 
  209. "Appendix I: The Past, Present and Future of Transmountain Diversion Projects". Roaring Fork Watershed Plan. Roaring Fork Conservancy. http://www.roaringfork.org/pub/collaborative/GDII%20Appendix%20I%20-%20Transmountain%20Diversion%20Projects.pdf. 
  210. "Transmountain Water Diversions". Colorado River District. July 2011. http://www.crwcd.org/media/uploads/20110719-policies_TMDs.pdf. 
  211. 211.0 211.1 211.2 Citizen's Guide to Colorado's Transbasin Diversions. Water Education Colorado. 2014. https://issuu.com/cfwe/docs/cfwe_cgtb_web. 
  212. "Transmountain Diversions". Roaring Fork Conservancy. http://www.roaringfork.org/your-watershed/watershed-facts/transmountain-diversions/. Retrieved May 18, 2022. 
  213. "Colorado-Big Thompson Project". U.S. Bureau of Reclamation. October 18, 2011. http://www.usbr.gov/projects/Project.jsp?proj_Name=Colorado-Big+Thompson+Project. 
  214. "Moving Water in the Watershed". Blue River Watershed Group. http://blueriverwatershed.org/water-quantity/moving-water-in-the-brw/. 
  215. Wahlstrom, Ernest E. (1974). "History of Geologic Investigations, Engineering Design, and Construction Methods of the Harold D. Roberts Tunnel, Colorado". Geological Survey Professional Paper 831–A (U.S. Geological Survey). http://pubs.usgs.gov/pp/0831a/report.pdf. 
  216. "Fryingpan–Arkansas Project". U.S. Bureau of Reclamation. May 10, 2011. http://www.usbr.gov/projects/Project.jsp?proj_Name=Fryingpan-Arkansas%20Project. 
  217. "Williams Fork Reservoir". Denver Water. https://www.denverwater.org/recreation/williams-fork-resevoir. Retrieved May 18, 2022. 
  218. "Wolford Mountain Reservoir". Colorado River District. https://www.coloradoriverdistrict.org/wolford-mountain-reservoir-2/. Retrieved May 18, 2022. 
  219. Billington, Jackson & Melosi 2005, p. 140.
  220. 220.0 220.1 Sperry, Robert L. (Winter 1975). "When The Imperial Valley Fought For Its Life". The Journal of San Diego History (San Diego History Center) 21 (1). https://sandiegohistory.org/journal/1975/january/imperial-2/. Retrieved June 25, 2023. 
  221. Patten, McCaskie and Unitt, pp. 4–5
  222. "Origin of the Salton Sea". Suburban Emergency Management Project. http://www.semp.us/publications/biot_reader.php?BiotID=505. 
  223. Billington, Jackson & Melosi 2005, pp. 141–142.
  224. "Boulder Canyon Project – Hoover Dam". U.S. Bureau of Reclamation. February 1, 2012. http://www.usbr.gov/projects/Project.jsp?proj_Name=Boulder%20Canyon%20Project%20-%20Hoover%20Dam. 
  225. "The Colorado River and Hoover Dam: Facts and Figures". U.S. Bureau of Reclamation. January 2012. http://www.usbr.gov/lc/region/pao/brochures/faq.html. 
  226. "Boulder Canyon Project Act (1928)". National Archives. September 21, 2021. https://www.archives.gov/milestone-documents/boulder-canyon-project-act. Retrieved May 18, 2022. 
  227. "All-American Canal, California–Mexico border". Earth Observatory. National Aeronautics and Space Administration. February 23, 2009. http://earthobservatory.nasa.gov/IOTD/view.php?id=37078. 
  228. "About IID Water". Imperial Irrigation District. https://www.iid.com/water/about-iid-water. Retrieved May 18, 2022. 
  229. "CRBSCP - Coachella Canal Unit - Title I". U.S. Bureau of Reclamation. https://www.usbr.gov/projects/index.php?id=492. Retrieved May 18, 2022. 
  230. "Parker Dam". Parker-Davis Project. U.S. Bureau of Reclamation. June 29, 2009. http://www.usbr.gov/projects/Facility.jsp?fac_Name=Parker+Dam&groupName=General. 
  231. Marie Bell, Tina (1997). "Gila Project". U.S. Bureau of Reclamation. http://www.usbr.gov/projects//ImageServer?imgName=Doc_1305042259136.pdf. 
  232. "The Colorado River: A Regional Solution". Los Angeles Department of Water and Power. http://wsoweb.ladwp.com/Aqueduct/historyoflaa/coloradoriver.htm. 
  233. "San Diego Project". U.S. Bureau of Reclamation. January 11, 2012. http://www.usbr.gov/projects/Project.jsp?proj_Name=San+Diego+Project. 
  234. "Nevada". Colorado River Water Users Association. http://www.crwua.org/colorado-river/member-states/nevada. 
  235. Fradkin 1996, p. 191.
  236. 236.0 236.1 236.2 "Colorado River Storage Project". U.S. Bureau of Reclamation. https://www.usbr.gov/uc/rm/crsp/index.html. 
  237. "Chapter IX: Dinosaur National Monument". A Survey of the Recreational Resources of the Colorado River Basin. U.S. National Park Service. September 6, 2004. http://www.nps.gov/history/history/online_books/colorado/chap9.htm. 
  238. "Historic Opposition to Glen Canyon Dam". The End of Lake Powell Campaign. Colorado Riverkeeper. July 20, 2004. http://www.drainit.org/campaigns/drought/facts3.cfm. 
  239. "Resurrection: Buried Treasure". National Audubon Society. 2006. http://archive.audubonmagazine.org/fieldnotes/fieldnotes0607.html. 
  240. "The Central Utah Project - An Overview". U.S. Department of the Interior. https://www.doi.gov/cupcao/Overview. Retrieved May 18, 2022. 
  241. Glaser, Leah S.. "San Juan-Chama Project". U.S. Bureau of Reclamation. https://www.usbr.gov/projects/pdf.php?id=186. Retrieved May 18, 2022. 
  242. 242.0 242.1 242.2 242.3 "Pacific Southwest Water Plan". U.S. Bureau of Reclamation. January 1964. https://www.usbr.gov/lc/region/programs/crbstudy/PSWPRptJan64.pdf. Retrieved May 18, 2022. 
  243. 243.0 243.1 "U.S. Plan for Dams on Colorado Under Fire by Conservationists; Interior Department Insists Projects Are Vital to Southwest's Development —National Battle Expected". The New York Times. March 15, 1964. https://www.nytimes.com/1964/03/15/archives/us-plan-for-dams-on-colorado-under-fire-by-conservationists.html. Retrieved May 18, 2022. 
  244. "Reclamation Helps Celebrate Theodore Roosevelt Dam's 100th Year". U.S. Bureau of Reclamation. March 2011. http://www.usbr.gov/lc/region/programs/Roosevelt/story.html. 
  245. Gerke, Sarah Bohl. "Bridge Canyon". Arizona State University. https://grcahistory.org/sites/colorado-river-corridor/bridge-canyon/. Retrieved May 18, 2022. 
  246. 246.0 246.1 "Central Arizona Project". U.S. Bureau of Reclamation. April 18, 2011. http://www.usbr.gov/projects/Project.jsp?proj_Name=Central+Arizona+Project. 
  247. Murdock, J. Neil (1996). "Bridge Canyon Dam". from Early History of the Colorado River Storage Project May 1971 U. S. Department of the Interior, Bureau of Reclamation. Grand Canyon River Guides. http://www.gcrg.org/bqr/10-1/bcd.html. 
  248. "Chapter VII: The Grand Canyon". A Survey of the Recreational Resources of the Colorado River Basin. U.S. National Park Service. September 6, 2005. http://www.nps.gov/history/history/online_books/colorado/chap7.htm. 
  249. "Navajo Generating Station, Project Information". Salt River Project. https://www.srpnet.com/about/stations/ngs/default.aspx. Retrieved May 18, 2022. 
  250. "Trinity River". U.S. Bureau of Reclamation. May 18, 2022. https://www.usbr.gov/mp/ncao/trinity-river.html. 
  251. Congressional Research Service (August 16, 2021). "Management of the Colorado River: Water Allocations, Drought, and the Federal Role". Federation of American Scientists. https://sgp.fas.org/crs/misc/R45546.pdf. Retrieved May 18, 2022. 
  252. Reisner 1993, p. 121.
  253. Reisner 1993, p. 126.
  254. Stahle, David W.; Fye, Falko K.; Therrell, Matthew D. (2003). "Interannual to Decadal Climate and Streamflow Variability Estimated from Tree Rings". Developments in Quaternary Science. Developments in Quaternary Sciences 1: 491–504. doi:10.1016/S1571-0866(03)01023-6. ISBN 9780444514707. 
  255. "Upper Colorado River Basin Consumptive Uses and Losses Report 2006-2010". U.S. Bureau of Reclamation. August 2012. http://www.usbr.gov/uc/library/envdocs/reports/crs/pdfs/cul2006-2010prov.pdf. 
  256. 256.0 256.1 Gelt, Joe (August 1997). "Sharing Colorado River Water: History, Public Policy and the Colorado River Compact". Arroyo (University of Arizona, Water Resources Research Center) 10 (1). http://worldcat.org/arcviewer/2/WCA/2009/12/14/H1260824596711/viewer/file2.html. Retrieved February 25, 2014. 
  257. Weisheit, John. "Persistent Drought in the Colorado River Basin". Confluence. http://www.riverguides.org/Confluence/27/27DroughtWeisheit.pdf. 
  258. "Paleoenvironmental Archives as a source of Climate Information for Natural Resource Management: An Example from Tree Rings and Colorado Water Management". U.S. Forest Service. http://www.fs.fed.us/psw/cirmount/policy/pdf/Paleo_Arc.pdf. 
  259. "Glen Canyon Dam Water Operations". U.S. Bureau of Reclamation. 2022. https://www.usbr.gov/uc/water/crsp/cs/gcd.html. 
  260. "Outlook for Water in the West at 2050". NOAA Earth System Research Laboratory, Climate Change Workshop. Western Water Assessment. November 17, 2006. http://wwa.colorado.edu/climate_change/docs/Hoerling%20v2%20WWA%20Front%20Range%20Water.pdf. 
  261. Kuhn, Eric (January 26, 2007). "The Colorado River's Uncertain Future: How Climate Change May Affect Future Planning Decisions on the Colorado River". CRWCD 49th Annual Convention. Colorado River Water Conservation District. http://www.crwcd.org/media/uploads/CO_River_Uncertain_Future.pdf. 
  262. Vernieu-Presenter, William S. (2005). "Current Status and Trends of Lake Powell and Glen Canyon Dam Release Water Quality". U.S. Geological Survey, Grand Canyon Monitoring and Research Center. Grand Canyon River Guides. http://www.gcrg.org/docs/gtslib/vernieu-05.pdf. 
  263. McKinnon, Shaun (October 19, 2010). "Lake Mead Sinks to a New Historic Low: If Lake Falls 8 More Feet, Thirsty Ariz. Could Experience Water Restrictions". The Arizona Republic (Phoenix, Arizona). http://www.azcentral.com/arizonarepublic/news/articles/2010/10/19/20101019lake-mead-water-level-new-historic-low.html. 
  264. Hiltzik, Michael (2014-06-20). "Water war bubbling up between California and Arizona". Los Angeles Times. http://www.latimes.com/business/hiltzik/la-fi-hiltzik-20140620-column.html#page=1. 
  265. McKinnon, Shaun (April 19, 2011). "Lake Mead Replenished by Snowfall". azcentral.com. http://www.azcentral.com/news/articles/2011/04/18/20110418lake-mead-replenished-by-snowfall.html. 
  266. Shine, Conor (August 17, 2011). "Lake Mead's water level rises 30 feet after wet winter". Las Vegas Sun. http://www.lasvegassun.com/news/2011/aug/17/lake-meads-water-level-rises/. 
  267. Perry, Tony (May 27, 2013). "As Colorado River drought worsens, water officials parley". Los Angeles Times. http://articles.latimes.com/2013/may/27/local/la-me-ln-as-drought-worsens-along-colorado-river-water-officials-discuss-moving-forward-20130527. 
  268. Johnson, Terrell (August 20, 2013). "Dwindling Colorado River Forces First-Ever Cuts in Lake Powell Water Releases". The Weather Channel. http://www.weather.com/news/science/environment/drought-lake-powell-lake-mead-climate-change-20130818. 
  269. Brean, Henry (2014-07-11). "Lake Mead sinks to a record low". Las Vegas Review-Journal. http://www.reviewjournal.com/news/nevada/lake-mead-sinks-record-low. 
  270. Sevigny, Melissa (2018-05-17). "Colorado River Water Shortage Could be Declared in 2020". KNAU. http://knau.org/post/colorado-river-water-shortage-could-be-declared-2020. 
  271. Chow, Lorraine (2018-05-17). "Unprecedented Colorado River Water Shortage Could Be Declared in 2020". EcoWatch. https://www.ecowatch.com/colorado-river-water-shortage-2569729456.html. 
  272. Brian Maffly (2021-07-22). "Lake Powell level about to hit a historic low as West's water crisis deepens". Salt Lake Tribune. https://www.sltrib.com/news/environment/2021/07/22/lake-powell-level-about/. 
  273. Michael Elizabeth Sakas (2021-07-24). "Lake Powell Just Hit Its Lowest Level On Record. Here's What That Means For Colorado And States That Rely On It". Colorado Public Radio. https://www.cpr.org/2021/07/24/lake-powell-lowest-water-level-on-record-heres-what-that-means-for-colorado-and-states-that-rely-on-it/. 
  274. Oliver Milman (2021-07-13). "Severe drought threatens Hoover dam reservoir – and water for US west". The Guardian. https://www.theguardian.com/us-news/2021/jul/13/hoover-dam-lake-mead-severe-drought-us-west. 
  275. "Reclamation announces 2022 operating conditions for Lake Powell and Lake Mead". United States Bureau of Reclamation. Aug 16, 2021. https://www.usbr.gov/newsroom/#/news-release/3950. 
  276. Budryk, Zack (Aug 17, 2021). "OVERNIGHT ENERGY: Federal government announces first-ever water shortage in Lake Mead, Colorado River |Biden administration releases guidance limiting international financing for fossil fuels |Biden administration to review federal coal leasing". MSN. https://www.msn.com/en-us/news/politics/overnight-energy-federal-government-announces-first-ever-water-shortage-in-lake-mead-colorado-river-biden-administration-releases-guidance-limiting-international-financing-for-fossil-fuels-biden-administration-to-review-federal-coal-leasing/ar-AANocbi. 
  277. "Full Committee Hearing To Examine Short And Long Term Solutions To Extreme Drought In The Western U.S.". United States Senate. https://www.energy.senate.gov/hearings/2022/6/full-committee-hearing-to-examine-short-and-long-term-solutions-to-extreme-drought-in-the-western-u-s. 
  278. Trotta, Daniel (28 October 2022). "U.S. warns western states it may impose Colorado River water cuts". Reuters. https://www.reuters.com/world/us/us-warns-western-states-it-may-impose-colorado-river-water-cuts-2022-10-28/. 
  279. Lochhead, Colton (15 December 2022). "Las Vegas water boss urges states to take action to keep lakes from crashing". Las Vegas Review Journal. https://www.reviewjournal.com/news/politics-and-government/las-vegas-water-boss-urges-states-to-take-action-to-keep-lakes-from-crashing-2695166/. 
  280. Partlow, Joshua (1 December 2022). "Officials fear 'complete doomsday scenario' for drought-stricken Colorado River". The Washington Post. https://www.washingtonpost.com/climate-environment/2022/12/01/drought-colorado-river-lake-powell/. 
  281. Christopher Flavelle (April 11, 2023). "White House Proposes Evenly Cutting Water Allotments From Colorado River". The New York Times. https://www.nytimes.com/2023/04/11/climate/colorado-river-water-cuts-drought.html. 
  282. 282.0 282.1 282.2 Christopher Flavelle (May 22, 2023). "Do-or-die talks reach deal to keep Colorado River from going dry, for now". The New York Times. https://www.sltrib.com/news/nation-world/2023/05/22/do-or-die-talks-reach-deal-keep/. 
  283. Ian James (8 April 2023). "Drought-ravaged Colorado River gets relief from snow. But long-term water crisis remains". The Los Angeles Times. https://www.latimes.com/environment/story/2023-04-08/colorado-river-snowpack-california. 
  284. Western states reach 'historic' deal to help save Colorado River
  285. House, The White (April 6, 2023). "FACT SHEET: Biden-Harris Administration Announces New Investments to Protect the Colorado River System". https://www.whitehouse.gov/briefing-room/statements-releases/2023/04/06/fact-sheet-biden-harris-administration-announces-new-investments-to-protect-the-colorado-river-system/. 
  286. "Biotic Communities of the Colorado Plateau: Riparian Areas". Land Use History of North America. Northern Arizona University. http://cpluhna.nau.edu/Biota/riparian_communities.htm. 
  287. Ohmart, Robert D.; Anderson, Bertin W.; Hunter, William C. (September 1988). "The Ecology of the Lower Colorado River from Davis Dam to the Mexico-United States International Boundary: A Community Profile". U.S. Fish and Wildlife Service. pp. 9, 12, 14. http://www.nwrc.usgs.gov/techrpt/85-7-19.pdf. 
  288. Shanahan, S.A.; Nelson, S.M.; Van Dooremolen, D.M.; Eckberg, J.R. (2011). "Restoring Habitat for Riparian Birds in the Lower Colorado River Watershed: An Example from the Las Vegas Wash, Nevada". Journal of Arid Environments 75 (11): 1182–1190. doi:10.1016/j.jaridenv.2011.06.017. Bibcode2011JArEn..75.1182S. http://www.lvwash.org/assets/pdf/resources_ecoresearch_birds_journal.pdf. Retrieved February 24, 2012. 
  289. Alles, David L. (August 8, 2007). "The Delta of the Colorado River". Western Washington University. http://fire.biol.wwu.edu/trent/alles/TheDelta.pdf. 
  290. "Riparian Vegetation: Structural Diversity Benefits Birds". University of California, Davis. https://www.geology.ucdavis.edu/~shlemonc/html/trips/Grand%20Canyon%20web/html/flogs/PDFs/structuralvegetation.pdf. 
  291. "Status of Plant and Animal Life". A Survey of the Recreational Resources of the Colorado River Basin. U.S. National Park Service. September 6, 2004. http://www.nps.gov/history/history/online_books/colorado/chap3a.htm. 
  292. Benke & Cushing 2005, p. 493.
  293. "130: Colorado". Freshwater Ecoregions of the World. January 11, 2012. http://www.feow.org/ecoregion_details.php?eco=130. 
  294. "Colorado River Basin Fish". Defenders of Wildlife. http://www.defenders.org/wildlife_and_habitat/wildlife/colorado_river_basin_fish.php. 
  295. Shao, Elena (May 22, 2023). "The Colorado River Is Shrinking. See What's Using All the Water.". The New York Times. https://www.nytimes.com/interactive/2023/05/22/climate/colorado-river-water.html.  ● Shao cites Richter, Brian D.; Bartak, Dominique; Cladwell, Peter; Davis, Kyle Frankel et al. (April 2020). "Water scarcity and fish imperilment driven by beef production". Nature Sustainability 3 (4): 319–328. doi:10.1038/s41893-020-0483-z. https://www.nature.com/articles/s41893-020-0483-z.epdf. 
  296. Gupta 2007, p. 200.
  297. "Why The Colorado River Stopped Flowing". National Public Radio. July 14, 2011. https://www.npr.org/sections/pictureshow/2011/07/15/137821595/why-the-colorado-river-stopped-flowing?singlePage=false. 
  298. Weisheit, John. "A Colorado River Sediment Inventory". Colorado Plateau River Guides. http://www.riverguides.org/Confluence/27/27SedimentWeisheit.pdf. 
  299. "Colorado River Basin". coriverbasin.org. http://www.coriverbasin.org. 
  300. "Colorado River System Consumptive Uses and Losses Report 1996–2000". U.S. Bureau of Reclamation. December 2004. http://www.usbr.gov/uc/library/envdocs/reports/crs/pdfs/crs962000.pdf. 
  301. Sandra Postel (April 5, 2013). "Landmark Cooperation Brings the Colorado River Home". National Geographic. http://newswatch.nationalgeographic.com/2013/04/05/landmark-cooperation-brings-the-colorado-river-home/. Retrieved May 19, 2014. 
  302. 302.0 302.1 Morford, Scott. "Salinity in the Colorado River Basin". https://watershed.ucdavis.edu/education/classes/files/content/page/6%20Morford-Colorado_Basin_Salinity.pdf. 
  303. "The Colorado River Salinity Problem: Direct Economic Damages in Mexico". University of Minnesota. June 1977. http://ageconsearch.umn.edu/bitstream/32180/1/01010007.pdf. 
  304. 304.0 304.1 "Colorado River Basin Salinity Control Program". Southern California Salinity Coalition. http://www.socalsalinity.org/pdfs/CRBSCPBriefingDocument.pdf. 
  305. "Colorado River Basin Salinity Control Project". U.S. Bureau of Reclamation. April 18, 2011. http://www.usbr.gov/projects/Project.jsp?proj_Name=Colorado+River+Basin+Salinity+Control+Project. 
  306. "Technical Report: Pesticides in the Lower Colorado River". Surveillance and Analysis Division, Report No. 002–73. U.S. Environmental Protection Agency. April 1973. http://nepis.epa.gov/Exe/ZyNET.exe/91008B82.TXT?ZyActionD=ZyDocument&Client=EPA&Index=Prior+to+1976&Docs=&Query=&Time=&EndTime=&SearchMethod=1&TocRestrict=n&Toc=&TocEntry=&QField=&QFieldYear=&QFieldMonth=&QFieldDay=&IntQFieldOp=0&ExtQFieldOp=0&XmlQuery=&File=D%3A%5Czyfiles%5CIndex%20Data%5C70thru75%5CTxt%5C00000008%5C91008B82.txt&User=ANONYMOUS&Password=anonymous&SortMethod=h%7C-&MaximumDocuments=1&FuzzyDegree=0&ImageQuality=r75g8/r75g8/x150y150g16/i425&Display=p%7Cf&DefSeekPage=x&SearchBack=ZyActionL&Back=ZyActionS&BackDesc=Results%20page&MaximumPages=1&ZyEntry=1&SeekPage=x&ZyPURL. 
  307. "About Region 7". Colorado River Basin Regional Water Quality Control Board. California Environmental Protection Agency. http://www.waterboards.ca.gov/coloradoriver/about_us/about_region7.shtml. 
  308. Polakovic, Gary. "A Sea in Trouble". The Press-Enterprise. San Diego State University. http://www.sci.sdsu.edu/salton/ASeaInTrouble.html. 
  309. "Pesticides in Surface Waters of the Upper Colorado River Basin, Colorado, 1996–98". Water-Resources Investigation Report 00-4005. U.S. Geological Survey. 2000. http://pubs.usgs.gov/wri/wri00-4005/pdf/wrir00-4005.pdf. 
  310. "Grand Canyon". Glen Canyon Institute. http://www.glencanyon.org/glen_canyon/grand-canyon. 
  311. Clarkson, Robert W.; Childs, Michael R. (May 8, 2000). "Temperature Effects of Hypolimnial-Release Dams on Early Life Stages of Colorado River Basin Big-River Fishes". Copeia 2000 (2): 402–412. doi:10.1643/0045-8511(2000)000[0402:teohrd2.0.co;2]. 
  312. Ghiglieri & Myers 2001, pp. 194–214.
  313. Margolis, Jason; Mullins, Lisa (November 26, 2012). "Colorado River Agreement to Help Restore Vanished Wetlands in Mexico". The World (Public Radio International). http://pri.org/stories/2012-11-26/colorado-river-agreement-help-restore-vanished-wetlands-mexico. 
  314. "Minute 319: Building on the Past to Provide for the Future". River Report. Water Education Foundation. 2012–2013. https://www.watereducation.org/userfiles/RiverReport_Winter13_web.pdf. 
  315. 315.0 315.1 Hodson, Hal (March 12, 2014). "Huge water pulse to bring Colorado river back from dead". New Scientist. https://www.newscientist.com/article/mg22129602.800-huge-water-pulse-to-bring-colorado-river-back-from-dead.html#.U3pqrijYJJQ. Retrieved May 19, 2014. 
  316. Hodson, Hal (May 19, 2014). "Colorado river reaches sea for first time in decades". New Scientist. https://www.newscientist.com/article/dn25587#.U3pqsyjYJJQ. Retrieved May 19, 2014. 
  317. Galvan, Astrid (May 19, 2014). "Colorado River Reaches Gulf". ABC and Associated Press. https://abcnews.go.com/US/wireStory/colorado-river-reaches-gulf-23753772. 
  318. Shorey, Ananda (December 23, 2004). "River May Be Getting More Rafters". Deseret News. Associated Press (Salt Lake City, Utah). http://www.deseretnews.com/article/600099792/River-may-be-getting-more-rafters.html. 
  319. Blond, Dunford & Schulte-Peevers 2008, p. 87.
  320. "River Trips/Permits". Grand Canyon National Park. U.S. National Park Service. July 25, 2011. http://www.nps.gov/grca/planyourvisit/whitewater-rafting.htm. 
  321. Jones, Melissa L. (June 9, 2006). "Rafting the Colorado River Through the Grand Canyon". azcentral.com. http://www.azcentral.com/travel/parks/grandcanyon/articles/2006/06/09/20060609story-rafting-CR.html. 
  322. 322.0 322.1 "Upper Colorado Special Recreation Management Area". U.S. Bureau of Land Management. September 29, 2011. http://www.blm.gov/co/st/en/fo/kfo/recreation_opportunities/rafting.html. 
  323. "Recreation Fee Account Accomplishments: Colorado River (Moab)". U.S. Bureau of Land Management. http://www.blm.gov/pgdata/etc/medialib/blm/ut/moab_fo/campgrounds/fee_accomplishment.Par.36998.File.dat/RecreationFeeAccountAccomplishmentsUT02Fy2011.pdf. 
  324. Powell 2003, p. 345.
  325. Armstead 1997, p. 143.
  326. "National Parks of the Colorado River Basin: Water Resources, Threats and Economics". National Parks Conservation Association. April 2011. http://www.npca.org/about-us/center-for-park-research/colorado_river_basin/Colorado-River-Report.pdf. 
  327. Driver, Nancy E. (April 15, 2013). "Effects of Mining on Water Quality in Upper Colorado River Basin". National Water-Quality Assessment Program – Upper Colorado River Basin Study Unit. U.S. Geological Survey. http://co.water.usgs.gov/nawqa/ucol/html/ofr_94_397_p16.html. 
  328. "Glen Canyon National Recreation Area Expanded Zebra Mussel Action Plan". Glen Canyon National Recreation Area. U.S. National Park Service. http://www.nps.gov/glca/parknews/upload/Expanded%20Action%20Plan.pdf. 
  329. "Lake Mead Proves Popular During Economic Downturn". Lake Mead National Recreation Area. U.S. National Park Service. February 5, 2009. http://www.nps.gov/lake/parknews/lake-mead-proves-popular-during-economic-downturn.htm. 
  330. O'Donoghue, Amy Joi (August 16, 2013). "Worst Colorado River drought in century prompts feds to cut releases from Lake Powell". Deseret News. http://www.deseretnews.com/article/865584776/Worst-Colorado-River-drought-in-century-prompts-feds-to-cut-releases-from-Lake-Powell.html?pg=all. 

Works cited

Further reading

  • Darrah, William Culp, Ralph V. Chamberlin, and Charles Kelly, editors. (2009). The Exploration of the Colorado River in 1869 and 1871–1872: Biographical Sketches and Original Documents of the First Powell Expedition of 1869 and the Second Powell Expedition of 1871–1872. ISBN:978-0-87480-963-3.
  • DeBuys, William (2011). A Great Aridness: Climate Change and the Future of the American Southwest. Oxford University Press. ISBN 978-0-19-977892-8. 
  • Fleck, Richard F., editor. (2000). A Colorado River Reader. ISBN:978-0-87480-647-2.
  • Fowler, Don D., editor. (2012). Cleaving an Unknown World: The Powell Expeditions and the Scientific Exploration of the Colorado Plateau. ISBN:978-1-60781-146-6.
  • Gregory, Herbert E., William Culp Darrah, and Charles Kelly, editors. (2009). The Exploration of the Colorado River and the High Plateaus of Utah by the Second Powell Expedition of 1871–1872. ISBN:978-0-87480-964-0.
  • Martin, Russell (1990). A Story That Stands Like A Dam: Glen Canyon and the Struggle for the Soul of the West (1 ed.). Henry Holt and Company. ISBN 978-0-8050-0822-7. https://archive.org/details/storythatstandsl00russ. 
  • Summitt, April R. (2013). Contested Waters: An Environmental History of the Colorado River. Boulder: University Press of Colorado. ISBN 978-1-60732-201-6. 


External links




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