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Droughts in California

Summary

Throughout history, California has experienced many droughts, such as 1841, 1864, 1924, 1928–1935, 1947–1950, 1959–1960, 1976–1977, 1986–1992, 2006–2010, 2011–2017, 2018 and 2020-[1][2] 2021. Precipitation in California is limited to a single, fairly short wet season, with the vast majority of rain and snowfall occurring in the winter months across the state. This delicate balance means that a dry rainy season can have lasting consequences. California is the most populous state and largest agricultural producer in the United States, and as such, drought in California can have a severe economic as well as environmental impact. The historical and ongoing droughts in California are caused by lack of rainfall (or snowfall), higher average temperatures, and drier air masses in the atmosphere. This leads to reduced residential, commercial, and industrial water security and less water availability in the natural environment and in snowpack, rivers, and reservoirs for human use; these water shortages can have major impacts on agriculture and other water-intensive land uses.

Percent area in U.S. drought monitor categories
A typical dry riverbed is seen in California, which is experiencing its worst megadrought in 1,200 years, precipitated by climate change,[3] facing an existential threat and is therefore water rationing.[4]

Climate changeEdit

According to the Intergovernmental Panel on Climate Change or IPCC, their Sixth Assessment Report (AR6) on the effects of climate change revealed a number of scientifically supported claims on what is to become the future of the earth. While variability in climate patterns are a natural occurrence, AR6 concluded that human influences have increased the chance of compound extreme weather events, specifically "increases in the frequency of concurrent heatwaves and droughts on the global scale" with high confidence.[5]

According to the NOAA Drought Task Force report of 2014, the drought is not part of a long-term change in precipitation and was a symptom of the natural variability, although the record-high temperature that accompanied the recent drought may have been amplified due to human-induced global warming.[6] This was confirmed by a 2015 scientific study which estimated that global warming "accounted for 8–27% of the observed drought anomaly in 2012–2014. Although natural variability dominates, anthropogenic warming has substantially increased the overall likelihood of extreme California droughts."[7] A study published in 2016 found that the net effect of climate change has made agricultural droughts less likely, with the authors also stating that "Our results indicate that the current severe impacts of drought on California’s agricultural sector, its forests, and other plant ecosystems have not been substantially caused by long-term climate change."[8]

Furthermore, global La Niña meteorological events are generally associated with drier and hotter conditions and further exacerbation of droughts in California and the Southwestern and to some extent Southeastern United States. Meteorological scientists have observed that La Niñas have become more frequent over time.[9]

Increasingly dramatic fluctuations in California weather have been observed in the 21st century. In 2015, California experienced its lowest snowpack in at least 500 years; the 2012–15 period was the driest in at least 1200 years.[10][11][12][13][14][15] However, the winter of 2016–17 was the wettest ever recorded in Northern California, surpassing the previous record set in 1982–83. In February 2017, Shasta, Oroville and Folsom Lakes were simultaneously dumping water into the ocean for flood control. Lake Oroville flowed over the emergency spillway for the first time in 48 years, after the main spillway was damaged resulting in the temporary evacuation of 200,000 people.[16] The combined inflow to Shasta, Oroville and Folsom Lakes on February 9 was 764,445 acre-feet (0.942929 km3). Two days later, the combined flood control release was 370,260 acre-feet (0.45671 km3).[17] This water would have been worth $370M at Los Angeles County municipal rates.

Dry yearsEdit

Since 1841, the following dry years have had significantly below-average precipitation.

  • 1841
  • 1863–64[2]
  • 1917–21
  • 1922–26
  • 1928–37
  • 1943–51
  • 1959–62
  • 1976–77
  • 1987–92
  • 1999-04
  • 2006–09
  • 2011-17
  • 2018
  • 2020-

1841Edit

The drought was so bad that "a dry Sonoma was declared entirely unsuitable for agriculture".[2]

1863–1864Edit

This drought was preceded by the torrential floods of 1861–1862.[2]

1924Edit

This drought encouraged farmers to start using irrigation more regularly. Because of the fluctuation in California weather, the need for consistent water availability was crucial for farmers.[2]

1928–1937Edit

This drought occurred during the infamous Dust Bowl period that ripped across the plains of the United States in the 1920s and 1930s.[2] The Central Valley Project was started in the 1930s in response to drought.[18]

1950sEdit

The 1950s drought contributed to the creation of the State Water Project.[18]

1976–77Edit

1977 had been the driest year in state history to date.[19] According to the Los Angeles Times, "Drought in the 1970s spurred efforts at urban conservation and the state's Drought Emergency Water Bank came out of drought in the 1980s.".[18]

Additionally as drought prediction was essentially random and in response to recent severe drought years, in 1977 the U.S. Department of the Interior, Office of Water Research and Technology contracted Entropy Limited for an exploratory study of the applicability of the entropy minimax method of statistical analysis of multivariate data to the problem of determining the conditional probability of drought one or two years into the future, with the area of special interest being California. Christensen et al. (1980) [20] demonstrated an information-theoretic model predicted the probability that precipitation will be below or above average with modest but statistically significant skill one, two and even three years into the future. It was this pioneering work that discovered the influence of El Nino El Nino-Southern Oscillation on US weather forecasting.

1986–1992Edit

California endured one of its longest droughts ever, observed from late 1986 through late 1992. Drought worsened in 1988 as much of the United States also suffered from severe drought. In California, the six-year drought ended in late 1992 as a significant El Niño event in the Pacific Ocean (and the eruption of Mount Pinatubo in June 1991) most likely caused unusual persistent heavy rains.[21]

2007–2009Edit

2007–2009 saw three years of drought conditions, the 12th worst drought period in the state's history, and the first drought for which a statewide proclamation of emergency was issued. The drought of 2007–2009 also saw greatly reduced water diversions from the state water project. The summer of 2007 saw some of the worst wildfires in Southern California history.[22]

2011–2017Edit

2011-2017 was the longest drought in California beginning December 2011 and ending March 2017.[1]

 
Progression of the drought from December 2013 to July 2014
 
Drought peak in late July 2014

The period between late 2011 and 2014 was the driest in California history since record-keeping began.[23] In May 2015, a state resident poll conducted by Field Poll found that two out of three respondents agreed that it should be mandated for water agencies to reduce water consumption by 25%.[24]

The 2015 prediction of El Niño to bring rains to California raised hopes of ending the drought. In the spring of 2015, the National Oceanic and Atmospheric Administration named the probability of the presence of El Niño conditions until the end of 2015 at 80%. Historically, sixteen winters between 1951 and 2015 had created El Niño. Six of those had below-average rainfall, five had average rainfall, and five had above-average rainfall. However, as of May 2015, drought conditions had worsened and above average ocean temperatures had not resulted in large storms.[25]

The drought led to Governor Jerry Brown's instituting mandatory 25 percent water restrictions in June 2015.[26]

Many millions of California trees died from the drought – approximately 102 million, including 62 million in 2016 alone.[27] By the end of 2016, 30% of California had emerged from the drought, mainly in the northern half of the state, while 40% of the state remained in the extreme or exceptional drought levels.[28] Heavy rains in January 2017 were expected to have a significant benefit to the state's northern water reserves, despite widespread power outages and erosional damage in the wake of the deluge.[29] Among the casualties of the rain was 1,000 year-old Pioneer Cabin Tree in Calaveras Big Trees State Park, which toppled on January 8, 2017.[30]

The winter of 2016–17 turned out to be the wettest on record in Northern California, surpassing the previous record set in 1982–83.[31] Floodwaters caused severe damage to Oroville Dam in early February, prompting the temporary evacuation of nearly 200,000 people north of Sacramento.[32] In response to the heavy precipitation, which flooded multiple rivers and filled most of the state's major reservoirs, Governor Brown declared an official end to the drought on April 7.[33]

EffectsEdit

Short-term effectsEdit

The runoff from rainfall used to support many aspects of California infrastructure, such as agriculture and municipal use, will be severely diminished during the drought. While groundwater diminishes at a much lower rate than runoff, the lack of runoff will lead to increased groundwater pumping to meet the needs of the water demand. If groundwater is being pumped at a rate higher than it can be replenished by precipitation then groundwater levels will begin to fall and the quality of water will also decrease. With that said the relationship between surface water and groundwater contribute to the hydrologic system, and groundwater helps maintain surface water flows during extended dry periods. With both sources diminishing, the quality and availability of water will decrease.

Long-term effectsEdit

Excessive ground water pumping and aquifer depletion will lead to land sinking and permanent loss of groundwater storage. Decreasing groundwater levels lead to exposing of underground water storage areas, this will cause lack of soil structure strength and possible sinking if the land above is heavy enough. This has already begun in certain parts of the state during the most recent drought. In coastal communities, excessive water pumping can lead to sea water intrusion, which means sea water will begin to flow into the underground water storage areas that were vacated by excess pumping. This can cause decreased water quality and lead to an expensive desalination effort to clean the water before distribution. Water flows through wildlife refuges and national parks can decrease or stop all together due to the decrease of surface and groundwater, the California Water Science Center is a part of a team trying to restore and maintain water flow in these at risk areas. With reduction of water flow and increased windy or dry weather, wildfire risks increase; lightning strikes or accidental human mistake can lead to huge wildfires due to the drier-than-normal climate.[34]

Possible AdaptationsEdit

Adaptation is the process of adjusting to circumstances, which means not trying to stop the drought, but trying to preserve the water given the drought conditions. This is the most used option, because stopping a drought is difficult given that it is a meteorological process. Adapting to the problem using innovation and problem solving is often the cheaper and more useful way to go because trying to change the natural processes of the earth could have unforeseen consequences.

Infrastructure issuesEdit

A precipitation shortage leaves less water in the state's water infrastructure systems, leading to debates on how to best make use of this limited resource.

Lack of new infrastructureEdit

Very few large-scale water projects have been built since 1979, despite the population doubling since that year.[36][37]

Inefficient distribution systemsEdit

Because much of California's water network relies on a system of pumps to move water from north to south, large volumes of water are often lost to the Pacific Ocean during winter storms when river flow exceeds the capacity of the pumps. This is further complicated by environmental rules which restrict pumping during certain months of the year, to protect migrating fish. In water year 2015, 9,400,000 acre-feet (11.6 km3) of water flowed through the Sacramento–San Joaquin River Delta, but only 1,900,000 acre-feet (2.3 km3) were recovered into water distribution systems.[38]

Reservoir capacity reserved for flood controlEdit

 
Dry boat ramp at Folsom Lake, January 2014

Most of California's major reservoirs serve important flood control functions. Due to the limited capacity of river channels and dam spillways, reservoirs cannot be quickly drained before major storms. This limits how much of a reservoir's capacity can be used for long-term storage. Reservoirs in California are designed to control either rain floods, snowmelt floods or both.

In the coastal and southern parts of the state, and much of the Sacramento River system, the primary threat is rain floods in the November–April wet season. Oceanic "atmospheric river" or Pineapple Express storms can generate massive precipitation in a short period (often up to 50 percent of the total annual rainfall in just a few storms).[39] This requires a certain safety margin to be maintained in reservoirs, which are often not allowed to capacity until late April or May. Shasta Lake, California's largest reservoir, is limited to approximately 71 percent of capacity in the winter in order to control rain flooding. Levees along Northern California rivers, such as the Sacramento and American rivers, are quite generously sized in order to pass large volumes of floodwater.[40]

In the San Joaquin River basin (San Joaquin Valley) and other areas of the state where snowpack is the primary source of river flow, river channels are sized mainly to control snowmelt floods, which do not produce the huge peaks typical of rain floods, but are longer in duration and have a much higher total volume. As a result, reservoirs in this region have very strict restrictions on the amount of water that can be released. An example of a reservoir operated for snow floods is Pine Flat Lake near Fresno, which is restricted to about 53 percent capacity well into spring in order to capture summer snowmelt.[41] However, Pine Flat and other San Joaquin reservoirs are frequently ineffectual in controlling rain floods, because they cannot release water fast enough between winter storms.[41][42]

 
In May 2021, water levels of Lake Oroville dropped to 38% of capacity. The boats are dwarfed by the exposed banks while California is headed into another drought year.

Certain parts of the state, especially in the central Sierra Nevada, are prone to both rain and snow floods. Reservoirs such as Lake Oroville and Folsom Lake must respond to a wider range of runoff conditions. Lake Oroville is typically limited to 79–89 percent of capacity during the winter and Folsom Lake to 33–60 percent. These values are often adjusted up and down based on the amount of rain and snow forecast.[40] At Folsom Lake, due to the small size of the reservoir, it is difficult to balance the need for winter flood-control space with the need to store water for the summer. This often results in a failure to fill the lake due to a lower than expected spring snowmelt. Water managers and hydrology experts have criticized the outdated, overly conservative operation criteria at Folsom Dam, citing improved weather forecasting and snowpack measurement technology.[43]

Progress in forecasting methods has allowed more efficient or "smart" operation at certain California reservoirs, such as Lake Mendocino. If dry weather is forecast, water is allowed to be stored above the legal flood control limit, rather than being wasted downstream. This program is known as "Forecast Informed Reservoir Operations".[44] In addition, capital improvements such as the $900 million spillway project at Folsom Dam[45] will allow greater flexibility in water releases, making it safer to maintain a high reservoir level during the wet season.

Flood control limitations at selected California reservoirs[41]
Reservoir River Capacity Max. flood
control
reservation 		Percent of total capacity reserved for flood control Target flood
water release
Acre feet km3 Acre feet km3 ft3/s m3/s
Shasta Lake Sacramento River 4,552,000 5.615 1,300,000 1.6 28.5% 79,000 2,200
Lake Oroville Feather River 3,540,000 4.37 750,000 0.93 21.1% 150,000 4,200
New Bullards Bar Reservoir Yuba River 966,000 1.192 170,000 0.21 17.6% 50,000 1,400
Folsom Lake American River 977,000 1.205 670,000 0.83 68.5% 115,000 3,300
Camanche Lake Mokelumne River 417,000 0.514 200,000 0.25 48.0% 5,000 140
New Hogan Lake Calaveras River 317,000 0.391 165,000 0.204 52.1% 12,500 350
New Melones Lake Stanislaus River 2,420,000 2.99 450,000 0.56 18.6% 8,000 230
Lake Don Pedro Tuolumne River 2,030,000 2.50 340,000 0.42 16.7% 9,000 250
Lake McClure Merced River 1,025,000 1.264 350,000 0.43 34.2% 6,000 170
Millerton Lake San Joaquin River 521,000 0.643 391,000 0.482 75.0% 8,000 230
Pine Flat Lake Kings River 1,000,000 1.2 475,000 0.586 47.5% 7,950 225
Lake Isabella[46] Kern River 568,000 0.701 398,000 0.491 70.1% 4,600 130

Weather cyclesEdit

California has one of the most variable climates of any U.S. state, and often experiences very wet years followed by extremely dry ones.[47] The state's reservoirs have insufficient capacity to balance the water supply between wet and dry years.

El Niño and La Niña have often been associated with wet and dry cycles in California, respectively (the 1982–83 El Niño event, one of the strongest in history, brought record precipitation to the state), but recent climate data show mixed evidence for such a relationship due in part to the growing impact of human-induced global warming. The very wet 2010–2011 season occurred during a strong La Niña phase, while the 2014–16 El Niño event, which surpassed 1982–83 in intensity, did not bring an appreciable increase of precipitation to the state.

The 2012–15 North American drought was caused by conditions of the Arctic oscillation and North Atlantic oscillation which removed storms from the U.S. in the winter of 2011–2012.

Large water consumersEdit

Approximately 5,100,000 acre-feet (6.3 km3) are used in California every year as cattle feed.[48]

Also, from 2008–2015, over 2,400,000 acre-feet (3.0 km3) (300,000 acre-feet (0.37 km3) per year) were released into the San Francisco Bay to save the endangered Delta smelt.[49] An alternative, salinity barriers, is being installed.[50]

Supply and demandEdit

Water in California can be expensive.[51] This leads to awareness of water management challenges.[52]

In rain-rich states and countries, which are not drought-prone, the water, as elsewhere, is managed by government consent, which assumes ownership and management of all free flowing rivers, lakes, and bodies of water in its parameters. The water being used for commercial purposes, such as Nestle's 72 brands of bottled water, is done so only as permitted and granted by governmental authorities. Lately, locals have been fighting back against the "stealing" of precious resources by opposing and not allowing huge water draw down facilities to be set up.[53] In some instances, water tables underground have dropped from 100 to 400–600 feet deep, basically shutting off most private well owners from their own water sources.[54]

Orange County is working toward water independence by building the world's largest indirect potable water recycling project – the Groundwater Replenishment System.[55] Poseidon Water is also developing a seawater desalination plant in Huntington Beach[56] for Orange County and has already built and is operating a seawater desalination plant in Carlsbad[57] for San Diego County. Combined the two plants will provide 100 million gallons of drinking water per day, or enough water for about 800,000 people.

Repeal of Government PoliciesEdit

After imposing a ban on urban landscape irrigation in 2014, the governor at the time quickly realized that this was a huge economic mistake.[citation needed] By discouraging extremely high-value use ($4,100/acre-ft considering $5.25/HCF base rate plus $5/HCF "administrative penalty" which exists even in non-drought times[58]) and encouraging low value use (such as sticky rice farming that cannot survive on $575/acre-ft[59]) the available funds for water infrastructure was reduced. This mistake was quickly corrected. Urban landscape irrigation (and its associated revenue) was resumed.[citation needed]

See alsoEdit

ReferencesEdit

  1. ^ a b "California | Drought.gov". www.drought.gov. Retrieved 2020-04-22.
  2. ^ a b c d e f "A History of Drought in California: Learning From the Past, Looking to the Future". Civil Eats. 2014-02-05. Retrieved 2017-05-03.
  3. ^ [1] Accessed June 13, 2022.
  4. ^ Irina Ivanova (June 2, 2022). "California is rationing water amid its worst drought in 1,200 years". CBS News. Retrieved June 4, 2022.
  5. ^ IPCC, 2021: Summary for Policymakers. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. Péan, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Mattews, T.K. Maycock, T. Waterfield, O. Yelekçi, R. Yu and B. Zhou (eds.)]. Cambridge University Press. In Press.
  6. ^ "Climate Program Office > Climate Programs > Modeling Analysis Predictions and Projections > MAPP Task Forces > Drought Task Force > California Drought". Archived from the original on March 2, 2015.
  7. ^ Williams, A. Park; et al. (2015). "Contribution of anthropogenic warming to California drought during 2012–2014". Geophysical Research Letters. 42 (16): 6819–6828. Bibcode:2015GeoRL..42.6819W. doi:10.1002/2015GL064924.
  8. ^ Cheng, Linyin; Hoerling, Martin; AghaKouchak, Amir; Livneh, Ben; Quan, Xiao-Wei; Eischeid, Jon (2016-01-01). "How Has Human-Induced Climate Change Affected California Drought Risk?". Journal of Climate. 29 (1): 111–120. Bibcode:2016JCli...29..111C. doi:10.1175/JCLI-D-15-0260.1. ISSN 0894-8755.
  9. ^ Seth Borenstein, Associated Press science writer (May 28, 2022). "Weather's unwanted guest: Nasty La Niña keeps popping up". 9news.com. Retrieved June 4, 2022. “Scientists are noticing that in the past 25 years the world seems to be getting more La Niñas than it used to…”
  10. ^ "California Just Had Its Worst Drought in Over 1200 Years". TheGuardian.com. 8 December 2014.
  11. ^ "California drought the worst in 1,200 years, new study says". 4 December 2014.
  12. ^ "California Drought Worst in 1,200 Years: Study".
  13. ^ "California's Drought Is Now the Worst in 1,200 Years".
  14. ^ "California Is In The Middle Of Its Worst Drought In 1,200 Years". HuffPost. 9 April 2015.
  15. ^ "California's worst drought in 1,200 years in pictures". BBC News. 2 April 2015.
  16. ^ "Thanks to storm runoff, there's a lot of water over California's second-largest reservoir". Los Angeles Times. 12 February 2017.
  17. ^ "Daily Reservoir Storage Summary".
  18. ^ a b c Curwen, Thomas (7 June 2015). "California drought: No rain, but 'the sky is not falling'". LA Times. Retrieved 8 June 2015.
  19. ^ The 1976–1977 California Drought: A Review (PDF). Department of Water Resources. May 1978.
  20. ^ Ronald A. Christensen and Richard F. Eilbert and Orley H. Lindgren and Laurel L. Rans (1980). "An Exploratory Application of Entropy Minimax to Weather Prediction: Estimating the Likelihood of Multi-Year Droughts in California". Monthly Weather Review. Vol. 113. p. 39. ISSN 0027-0644.
  21. ^ Water Resources Support Center, Institute For Water Resources, U.S. Army Corps of Engineers (1992). Lessons learned from the California Drought (1987–1992). ASCE Publications. p. 122. ISBN 978-0-7881-4163-8. Retrieved 2013-06-11.{{cite book}}: CS1 maint: multiple names: authors list (link)
  22. ^ California's Drought of 2007–2009: An Overview (PDF). California Department of Water Resources. September 2010. pp. 1–2.
  23. ^ Ellen Hanak; Jeffrey Mount; Caitrin Chappelle (January 2015). "California's Latest Drought". PPIC.
  24. ^ Alexander, Kurtis (19 May 2015). "California drought: People support water conservation, in theory". SF Gate. Retrieved 20 May 2015.
  25. ^ Rogers, Paul (14 May 2015). "California drought: El Niño conditions strengthening, but don't break out the galoshes yet". San Jose Mercury News. Retrieved 20 May 2015.
  26. ^ "The California drought: What would you ask Gov. Jerry Brown?". USC News. 8 June 2015. Retrieved 10 June 2015.
  27. ^ USDA Office of Communications (2016-11-18). "New Aerial Survey Identifies More Than 100 Million Dead Trees in California". USDA/U.S. Forest Service. Retrieved 22 November 2016.
  28. ^ USDA Brad Rippey (2016-12-26). "U.S. Drought Monitor California". Archived from the original on 27 December 2016. Retrieved 28 December 2016.
  29. ^ Rogers, Paul (January 9, 2017). "California storms add 350 billion gallons to parched reservoirs". The Mercury News (San Jose). Bay Area News Group. Retrieved 10 January 2017.
  30. ^ Andrews, Travis M. (January 9, 2017). "Morning Mix: Winter storm fells one of California's iconic drive-through tunnel trees, carved in the 1880s". The Washington Post. Retrieved January 10, 2017.
  31. ^ Parvini, Sarah (2017-04-13). "Northern California gets its wettest winter in nearly a century". Los Angeles Times. Retrieved 2017-04-16.
  32. ^ Park, Madison; McLaughlin, Eliott C. (2017-02-13). "Evacuations ordered over concerns at California dam system". CNN. Retrieved 2017-04-16.
  33. ^ "California's drought is officially over, Gov. Jerry Brown says". CBS News. Associated Press. 2017-04-07. Retrieved 2017-04-16.
  34. ^ Center, U.S. Geological Survey California Water Science. "Impacts of Drought | USGS California Water Science Center". ca.water.usgs.gov. Retrieved 2017-05-03.
  35. ^ "California's Drought: Adapting and Mitigating". Retrieved 2017-05-03.
  36. ^ "California Drought: Bad Policy, Poor Infrastructure". National Review. July 2015.
  37. ^ "California Faces Lost Decades in Solving Drought". Wall Street Journal. 25 December 2015.
  38. ^ "Day Flow Calculations 2015".
  39. ^ "Archived copy". Archived from the original on 2017-05-14. Retrieved 2017-05-03.{{cite web}}: CS1 maint: archived copy as title (link)
  40. ^ a b http://www.water.ca.gov/storage/docs/NODOS%20Project%20Docs/NODOS_Prelim_Admin_Draft_EIR/09-Flood_Control_prelim_admin_draft_Dec2013_w_figures.pdf[bare URL PDF]
  41. ^ a b c U.S. Army Corps of Engineers. "Central Valley Flood Management Systems" (PDF). Auburn Dam Council. Archived from the original (PDF) on 2016-03-11. Retrieved 2017-05-02.
  42. ^ https://www.usbr.gov/mp/sccao/storage/docs/phase1_rpt_fnl/tech_app/09_pine_flat.pdf[bare URL PDF]
  43. ^ http://www.sacbee.com/news/state/california/water-and-drought/article60419396.html[bare URL]
  44. ^ "FIRO_Overview – Center for Western Weather and Water Extremes".
  45. ^ "Sacramento District > Missions > Civil Works > Folsom Water Control Manual Update".
  46. ^ Although the nominal capacity is 568,000 acre feet, Lake Isabella is currently limited to 360,000 acre foot capacity due to structural problems with the dam.[citation needed]
  47. ^ "California's Wild Climate Will Only Get More Volatile as Temperatures Rise". HuffPost. 3 March 2017.
  48. ^ "Cows Not Almonds Are Biggest Water Users".
  49. ^ Finley, Allysia (26 April 2015). "Forget The Missing Rainfall. Where's the Delta Smelt?". Wall Street Journal.
  50. ^ "Drought Triggers Need for Installation of Emergency Salinity Barrier on Delta Channel". Archived from the original on 2015-04-26. Retrieved 2016-01-06.
  51. ^ "LA County Water Rates".
  52. ^ "California Drought".
  53. ^ "Groveland Battling Water Bottler (Niagra) to Preserve Chance of Future Growth".
  54. ^ "Nestle Outbids Township That Wanted Well For Drinking Water".
  55. ^ Groundwater Replenishment System
  56. ^ seawater desalination plant in Huntington Beach
  57. ^ seawater desalination plant in Carlsbad
  58. ^ "Administrative Penalties | las Virgenes Municipal Water District".
  59. ^ Sengupta, Somini (28 June 2021). "It's Some of America's Richest Farmland. But What is It Without Water?". The New York Times.

External linksEdit

  • State of California: drought
  • United States drought monitor for California
  • USGS: California Water Science Center, Drought
  • Department of Water Resources: California Data Exchange Center, and CDEC daily drought summary

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