Mapping groundwater storage variations with GRACE: a case study in Alberta, Canada

Huang, Jianliang; Pavlic, G; Rivera, Alfonso; Palombi, Dan; Smerdon, Brian

doi:10.1007/s10040-016-1412-0

Cited by 37 publications

(16 citation statements)

References 37 publications

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“…In recent years, there have been many studies of the retrieval of groundwater changes in different regions using the GRACE satellite gravity data and hydrological models. These studies have been performed in areas including the Mississippi River basin [8], Northern India [9,10], the Mid-Atlantic Region [11], East Africa [12], the Indus Basin in Pakistan [13], the Tibetan Plateau [14], the Three Gorges Reservoir of China [15], the North China Plain [2,16], Alberta in Canada [17], the whole area of Jordan [18], and other regions [19][20][21]. These studies found good correspondence between GWS changes from GRACE and situ GWS changes from monitoring wells, which indicate that GRACE shows great potential for monitoring large-scale GWS changes.…”

Section: Introductionmentioning

confidence: 99%

Monitoring Groundwater Storage Changes in the Loess Plateau Using GRACE Satellite Gravity Data, Hydrological Models and Coal Mining Data

Xie

Wen

et al. 2018

Remote Sensing

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Monitoring the groundwater storage (GWS) changes is crucial to the rational utilization of groundwater and to ecological restoration in the Loess Plateau of China, which is one of the regions with the most extreme ecological environmental damage in the world. In this region, the mass loss caused by coal mining can reach the level of billions of tons per year. For this reason, in this work, in addition to Gravity Recovery and Climate Experiment (GRACE) satellite gravity data and hydrological models, coal mining data were also used to monitor GWS variation in the Loess Plateau during the period of 2005-2014. The GWS changes results from different GRACE solutions, that is, the spherical harmonics (SH) solutions, mascon solutions, and Slepian solutions (which are the Slepian localization of SH solutions), were compared with in situ GWS changes, obtained from 136 groundwater observation wells, and the aim was to acquire the most robust GWS changes. The results showed that the GWS changes from mascon solutions (mascon-GWS) match best with in situ GWS changes, showing the highest correlation coefficient, lowest root mean square error (RMSE) values and nearest annual trend. Therefore, the Mascon-GWS changes are used for the spatial-temporal analysis of GWS changes. Based on which, the groundwater depletion rate of the Loess Plateau was −0.65 ± 0.07 cm/year from 2005-2014, with a more severe consumption rate occurring in its eastern region, reaching about −1.5 cm/year, which is several times greater than those of the other regions. Furthermore, the precipitation and coal mining data were used for analyzing the causes of the groundwater depletion: the results showed that seasonal changes in groundwater storage are closely related to rainfall, but the groundwater consumption is mainly due to human activities; coal mining in particular plays a major role in the serious groundwater consumption in eastern region of the study area. Our results will help in groundwater resource management, ecological restoration, and policy planning for coal mining and economic development.

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Section: Introductionmentioning

confidence: 99%

Monitoring Groundwater Storage Changes in the Loess Plateau Using GRACE Satellite Gravity Data, Hydrological Models and Coal Mining Data

Xie

Wen

et al. 2018

Remote Sensing

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“…Much before the current digital revolution, there has been a long record of using remote sensing technologies to address this challenge, going back at least to the launch of Landsat-1 (then called Earth Resources Technology Satellite) in 1972, followed more recently by the era of Earth Observing Systems (EOS) with the launch of the Terra satellite in 1999 (Melesse et al, 2007). Remote sensing has been extensively used to monitor, among other things, the status of forest resources (Lefsky et al, 2002), larger mammals and birds in open habitats (Leyequien et al, 2007), capture fisheries (Santos, 2000), and ground water resources (Huang et al, 2016). Another example, at a more local level, is the detection via remote sensing of increased turbidity in the Northern Poyang Lake, the People's Republic of China (hereafter "China"), which resulted in a ban on sand mining (Wu et al, 2007;de Leeuw, 2010).…”

Section: Improving the Monitoring And Supervision Of Imperfectly Obsementioning

confidence: 99%

Using digital technologies to improve the design and enforcement of public policies

2019

OECD Digital Economy Papers

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“…Estimates of groundwater storage using the remote sensing have been performed around the globe (Swenson et al, 2006;Rodell et al, 2007Rodell et al, , 2009Strassberg et al, 2007;Tiwari et al, 2009;Scanlon et al, 2012;Shamsudduha et al, 2012;Voss et al, 2013;Bhanja et al, 2014Bhanja et al, , 2016Bhanja et al, , 2017bBhanja et al, , 2018Richey et al, 2015;Panda and Wahr, 2016;Chen et al, 2016;. Huang et al (2016) used remote-sensing data for computing the groundwater storage anomalies (GWSAs) in order to estimate groundwater storage in Alberta. They used groundwater levels (GWLs) at 36 wells, mostly confined to the southern Alberta region, and were correlated with both the GRACE terrestrial water storage (TWS) and groundwater storage variations.…”

Section: Introductionmentioning

confidence: 99%

Estimating long-term groundwater storage and its controlling factors in Alberta, Canada

Bhanja

Zhang

Wang

2018

Hydrol. Earth Syst. Sci.

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Groundwater is one of the most important natural resources for economic development and environmental sustainability. In this study, we estimated groundwater storage in 11 major river basins across Alberta, Canada, using a combination of remote sensing (Gravity Recovery and Climate Experiment, GRACE), in situ surface water data, and land surface modeling estimates (GWSA sat ). We applied separate calculations for unconfined and confined aquifers, for the first time, to represent their hydrogeological differences. Storage coefficients for the individual wells were incorporated to compute the monthly in situ groundwater storage (GWSA obs ). The GWSA sat values from the two satellitebased products were compared with GWSA obs estimates. The estimates of GWSA sat were in good agreement with the GWSA obs in terms of pattern and magnitude (e.g., RMSE ranged from 2 to 14 cm). While comparing GWSA sat with GWSA obs , most of the statistical analyses provide mixed responses; however the Hodrick-Prescott trend analysis clearly showed a better performance of the GRACE-mascon estimate. The results showed trends of GWSA obs depletion in 5 of the 11 basins. Our results indicate that precipitation played an important role in influencing the GWSA obs variation in 4 of the 11 basins studied. A combination of rainfall and snowmelt positively influences the GWSA obs in six basins. Water budget analysis showed an availability of comparatively lower terrestrial water in 9 of the 11 basins in the study period. Historical groundwater recharge estimates indicate a reduction of groundwater recharge in eight basins during . The output of this study could be used to develop sustainable water withdrawal strategies in Alberta, Canada.Published by Copernicus Publications on behalf of the European Geosciences Union.

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Mapping groundwater storage variations with GRACE: a case study in Alberta, Canada

Cited by 37 publications

References 37 publications

Monitoring Groundwater Storage Changes in the Loess Plateau Using GRACE Satellite Gravity Data, Hydrological Models and Coal Mining Data

Monitoring Groundwater Storage Changes in the Loess Plateau Using GRACE Satellite Gravity Data, Hydrological Models and Coal Mining Data

Using digital technologies to improve the design and enforcement of public policies

Estimating long-term groundwater storage and its controlling factors in Alberta, Canada

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