Hydroelectric power in the United States



Hydroelectricity is, as of 2019, the second-largest renewable source of energy in both generation and nominal capacity (behind wind power) in the United States. In 2021, hydroelectric power produced 31.5% of the total renewable electricity, and 6.3% of the total U.S. electricity.

According to the International Hydropower Association, the United States is the 3rd largest producer of hydroelectric power in the world in 2021 after Brazil and China. Total installed capacity for 2020 was 102,8 GW. The installed capacity was 80 GW in 2015. The amount of hydroelectric power generated is strongly affected by changes in precipitation and surface runoff.

Hydroelectric stations exist in at least 34 US states. The largest concentration of hydroelectric generation in the US is in the Columbia River basin, which in 2012 was the source of 44% of the nation's hydroelectricity. Hydroelectricity projects such as Hoover Dam, Grand Coulee Dam, and the Tennessee Valley Authority have become iconic large construction projects.

Of note, however, is that California does not consider power generated from large hydroelectric facilities (facilities greater than 30 megawatts) to meet its strictest definition of "renewable", due to concerns over the environmental impact of large hydroelectric projects. As such, electricity generated from large hydroelectric facilities does not count toward California's strict Renewable Portfolio Standards, even though other states recognize that water is a renewable resource in the hydrological cycle. Roughly about 10 to 15 percent of California's energy generation is from large hydroelectric generation that is not RPS-eligible.

The significant impact of dams on the power sector, water use, river flow, and environmental concerns requires significant policy specific to hydropower.

History


The earliest hydroelectric power generation in the U.S. was utilized for lighting and employed the better understood direct current (DC) system to provide the electrical flow. It did not flow far however, with ten miles being the system's limit; solving electricity's transmission problems would come later and be the greatest incentive to the new hydroelectric water-power developments.

The first DC powerhouse was in Grand Rapids, Michigan, where the water turbine at the Wolverine Chair factory was attached to a dynamo using a mechanical belt drive to illuminate sixteen street lights. This occurred in 1880, the same year Thomas Edison produced the long-lasting incandescent filament light bulb, which was a safety and convenience improvement over existing candles, whale oil lamps and kerosene lamps inside buildings. In 1881, also using DC for lighting at Niagara Falls, Jacob F. Schoellkopf diverted part of the output from his waterwheel-powered flour mills to drive one of Charles Brush's improved generators to provide nighttime illumination for the tourists. Previously the attraction had been illuminated by burning bright calcium flares but arc-lights proved a better and cheaper alternative.

In 1882, the world's first commercial central DC hydroelectric power plant provided power for a paper mill in Appleton, Wisconsin. Just months later the first investor-owned electric utility, Edison Illuminating Company, completed the first fossil fueled electrical power plant in New York City, to compete with hydroelectric power close to an area of high demand. By 1886, between 40 and 50 hydroelectric stations were operating in the United States and in Canada. By 1888, about 200 electric companies relied on hydropower for at least part of their generation.

Recognizing that the great hydroelectric potential of the Falls exceeded the local demand for electricity, a large power company was established nonetheless at the prime location for development; it awaited the prospect of an effective long-distance power transmission system. Westinghouse Electric won the competition, developing their plans around an alternating current system. The station was completed in 1895 and in 1896, electricity transmission 20 miles away to Buffalo, New York began. This event also began the rise to dominance of the AC system over Thomas Edison's direct current methods. Multiple permanent hydropower stations still exist on both the American and Canadian sides of the Falls, including the Robert Moses Niagara Power Plant, the third largest in the United States.

The need to provide rural development in the early 20th century was often coupled to the availability of electric power and led to large-scale projects like the Tennessee Valley Authority which created numerous dams and, sometimes controversially, flooded large areas. In the 1930s, the need for power in the Southwest led to the building of the largest concrete construction in the world at that time, the Hoover Dam. The Grand Coulee Dam was both a power and irrigation project of the 1930s that was expanded for military industrial reasons during World War II, which also saw other dams such as the TVA's Fontana Dam built.

Dam building peaked in the 1960s and few dams were built in the 1970s. The growing awareness of environmental issues with dams saw the removal of some older and smaller dams and the installation of fish ladders at others. The enormous Rampart Dam was canceled in 1967 due to environmental and economic concerns. Instead of new dams, repowering old stations has increased the capacity of several facilities. For instance, Hoover Dam replaced its generators between 1986 and 1993. The need to alter downstream waterflow for ecological reasons (eliminating invasive species, sedimentation, etc.) has led to regulated seasonal drawdowns at some dams, changing the availability of water for power generation. Droughts and increased agricultural use of water can also lead to generation limits.

According to a United States Department of Energy report, there exists over 12,000 MW of potential hydroelectricity capacity in the US existing 80,000 unpowered dams. Harnessing the currently unpowered dams could generate 45 TWhr/yr, equivalent to 16 percent of 2008 hydroelectricity generation.

According to a 2022 study, hydroelectric dams constructed prior to 1950 spurred short-run local economic growth due to cheaper power for localities. After 1950, the impact of hydropower dams on localities was more muted, most likely due to innovations such as high-tension transmission lines which dispersed the energy produced by dams to larger areas.

Pumped storage
Another application of hydroelectricity is Pumped-storage hydroelectricity which does not create a net gain in power, but enables peak demand balancing. Water is pumped from a lower elevation source into a higher one and only released through generators when electric demand is high. In 2009 the United States had 21.5 GW of pumped storage generating capacity, accounting for 2.5% of baseload generating capacity. This increased to a total of 22,878 MW in 2019 and 22,894 MW in 2020.

Bath County Pumped Storage Station is the largest such facility in the world. Other stations of this type include Raccoon Mountain Pumped-Storage Plant, Bear Swamp Hydroelectric Power Station and Ludington Pumped Storage Power Plant on Lake Michigan, previously the largest in the world.

Tidal power
No significant tidal power plants exist in the United States. A project was proposed and run by the Snohomish County PUD in Washington but was ended when trouble was encountered obtaining enough funding.

Largest hydroelectric power stations


This is a list of the ten largest hydroelectric power stations in the United States by installed capacity.

Non-powered dams hydroelectric potential
There are over 80,000 Non-powered dams (NPDs) in the United States that could add 12 GW of nameplate capacity or 45 terawatt hours (TWh) per year. The top 100 NPDs alone could add 8 GW, which could add 15% to hydroelectric generation of the 78 GW that was online in 2012. 81 of the top 100 NPDs are owned by the Army Corps of Engineers, the U.S. Bureau of Reclamation owns NPDs that could generate 260 MW.

Other non-powered dams

 * A. I. Selden Dam (Alabama)
 * Imperial Dam (California/Arizona)
 * Palo Verde Dam (California)
 * Chatfield Dam (Colorado)
 * John Martin Reservoir (Colorado)
 * Olmsted Locks and Dam (Illinois/Kentucky)
 * Red Rock Dam (Iowa)
 * Saylorville Lake (Iowa)
 * Dewey Dam (Kentucky)
 * Barren River Lake Dam (Kentucky)


 * Jordan Lake (North Carolina)
 * John C. Stennis Lock and Dam (Mississippi)
 * Ross Barnett Reservoir (Mississippi)
 * Grenada Dam (Mississippi)
 * Arkabutla Lake (Mississippi)
 * Coon Rapids Dam (Minnesota)
 * Lake Wister (Oklahoma)
 * Oologah Lake (Oklahoma)
 * Adam T. Bower Memorial Dam (Pennsylvania)


 * Lake Corpus Christi (Texas)
 * De Cordova Bend Dam (Texas)
 * Lake Houston Dam (Texas)
 * Belton Dam (Texas)
 * Tygart Dam (West Virginia)
 * Bluestone Dam (West Virginia)
 * Sutton Lake (West Virginia)
 * Howard A. Hanson Dam (Washington)
 * Lake Altoona (Wisconsin)