An examination of the sensitivity of the Great Salt Lake to changes in inputs

Mohammed, Ibrahim Nourein; Tarboton, David G.

doi:10.1029/2012wr011908

Cited by 56 publications

(40 citation statements)

References 41 publications

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“…1/2 cycle) (Dai 2012, Wang et al 2012 [24,20]. Likewise, the three-year and six-year lags in GSL are coincident with a quarter-phase and half-phase of the energetic ~12-year cycle, respectively, that characterizes the Great Basin precipitation (Smith et [30] pointed out that decadal precipitation trends may be causing the persistent Figure 11. The observed values for the 10-year moving average (black) shown with the predictions (red) 10 years out for the best annual model and the predictions (blue) 10 years out for the best moving-average model.…”

Section: Discussionmentioning

confidence: 95%

Feasibility of Multi-Year Forecast for the Colorado River Water Supply: Time Series Modeling

Plucinski

Sun

Wang

et al. 2019

Water

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The future of the Colorado River water supply (WS) affects millions of people and the US economy. A recent study suggested a cross-basin correlation between the Colorado River and its neighboring Great Salt Lake (GSL). Following that study, the feasibility of using the previously developed multi-year prediction of the GSL water level to forecast the Colorado River WS was tested. Time-series models were developed to predict the changes in WS out to 10 years. Regressive methods and the GSL water level data were used for the depiction of decadal variability of the Colorado River WS. Various time-series models suggest a decline in the 10-year averaged WS since 2013 before starting to increase around 2020. Comparison between this WS prediction and the WS projection published in a 2012 government report (derived from climate models) reveals a widened imbalance between supply and demand by 2020, a tendency that is confirmed by updated WS observation. Such information could aid in management decision-making in the face of near-future water shortages.

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Section: Discussionmentioning

confidence: 95%

Feasibility of Multi-Year Forecast for the Colorado River Water Supply: Time Series Modeling

Plucinski

Sun

Wang

et al. 2019

Water

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“…In South America, the largest closed lake in Central Argentina, Mar Chiquita, increased in area by 250% (from 2,000 to 6,500 km 2 ) between 1970 and 2003, and it is now slowly receding (Piovano et al ., ; Troin et al ., ). In the United States (U.S.), the Great Salt Lake, the fourth largest closed lake in the world, has been fluctuating by over 5 m since 1850; it reached its historically low level in 1963, gradually increased to its highest level in 1987, and then began receding again (Mohammed et al ., ). These lake level fluctuations, which are driven by changes in the climate and land management practices, led to significant negative ecological, economic, and social impacts in the region (Bedford, ).…”

Section: Introductionmentioning

confidence: 97%

Considering Climate Change in the Estimation of Long‐Term Flood Risks of Devils Lake in North Dakota

Kharel

Kirilenko

2015

J American Water Resour Assoc

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Terminal lakes are impacted by regional changes in climate. Devils Lake (DL), North Dakota, United States (U.S.), is a case in which a prolonged shift in the precipitation pattern resulted in a 10-m waterlevel rise over the past two decades, which cost over one billion U.S. dollars in mitigation. Currently, DL is 1.5 m from an uncontrolled overspill to the nearby Sheyenne River, which could lead to unprecedented environmental, social, and economic costs. Water outlets recently implemented in the lake to slow the water-level rise and prevent an uncontrolled overspill are subject to significant concerns over the introduction of invasive species and downstream water quality. We developed a hydrological model of the DL basin using the soil and water assessment tool and analyzed DL's overspill probability using an ensemble of statistically downscaled General Circulation Model (GCM) projections of the future climate. The results indicate a significant likelihood (7.3-20.0%) of overspill in the next few decades in the absence of outlets; some members of the GCM integration ensemble suggest an exceedance probability of over 85.0 and 95.0% for the 2020s and 2050s, respectively. Fullcapacity outlets radically reduce the probability of DL overspill and are able to partially mitigate the problem by decreasing the average lake level by approximately 1.9 and 1.5 m in the 2020s and 2050s, respectively.

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“…These alarming cases of lake level decline as well as other less dramatic incidents have been subjects of climate change scenario and impact assessments around the world (e.g. Coe and Foley 2001, Schwartz et al 2004, Ma et al 2010, Mohammed and Tarboton 2012, Shadkam et al 2016. Water level serves as a key indicator of a lake's stability (Ma et al 2010).…”

Section: Introductionmentioning

confidence: 99%

Climate-informed environmental inflows to revive a drying lake facing meteorological and anthropogenic droughts

Alborzi

Mirchi

Moftakhari

et al. 2018

Environ. Res. Lett.

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The rapid shrinkage of Lake Urmia, one of the world's largest saline lakes located in northwestern Iran, is a tragic wake-up call to revisit the principles of water resources management based on the socio-economic and environmental dimensions of sustainable development. The overarching goal of this paper is to set a framework for deriving dynamic, climate-informed environmental inflows for drying lakes considering both meteorological/climatic and anthropogenic conditions. We report on the compounding effects of meteorological drought and unsustainable water resource management that contributed to Lake Urmia's contemporary environmental catastrophe. Using rich datasets of hydrologic attributes, water demands and withdrawals, as well as water management infrastructure (i.e. reservoir capacity and operating policies), we provide a quantitative assessment of the basin's water resources, demonstrating that Lake Urmia reached a tipping point in the early 2000s. The lake level failed to rebound to its designated ecological threshold (1274 m above sea level) during a relatively normal hydro-period immediately after the drought of record (1998)(1999)(2000)(2001)(2002). The collapse was caused by a marked overshoot of the basin's hydrologic capacity due to growing anthropogenic drought in the face of extreme climatological stressors. We offer a dynamic environmental inflow plan for different climate conditions (dry, wet and near normal), combined with three representative water withdrawal scenarios. Assuming effective implementation of the proposed 40% reduction in the current water withdrawals, the required environmental inflows range from 2900 million cubic meters per year (mcm yr −1 ) during dry conditions to 5400 mcm yr −1 during wet periods with the average being 4100 mcm yr −1 . Finally, for different environmental inflow scenarios, we estimate the expected recovery time for re-establishing the ecological level of Lake Urmia.

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An examination of the sensitivity of the Great Salt Lake to changes in inputs

Cited by 56 publications

References 41 publications

Feasibility of Multi-Year Forecast for the Colorado River Water Supply: Time Series Modeling

Feasibility of Multi-Year Forecast for the Colorado River Water Supply: Time Series Modeling

Considering Climate Change in the Estimation of Long‐Term Flood Risks of Devils Lake in North Dakota

Climate-informed environmental inflows to revive a drying lake facing meteorological and anthropogenic droughts

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