Geodetic Constraints on the Qinghai-Tibetan Plateau Present-Day Geophysical Processes

Erkan, Kamil; Shum, C. K.; Wang, Lei; Guo, Junyi; Jekeli, Christopher; Lee, Hyongki; Panero, W. R.; Duan, Jielin; Huang, Zheng; Wang, Hansheng

doi:10.3319/tao.2010.09.27.01(tibxs)

Cited by 11 publications

(6 citation statements)

References 42 publications

(82 reference statements)

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“…The signal amplitudes become smaller from south to north in the Tibetan Plateau. These patterns are simi- (Rodell et al, 2004) and CPC data (Fan and van den Dool, 2004), (b) ICESat-1 based glacier measurements (Gardner et al, 2013), (c) monthly GLDAS (CLM/NOAH/MOSIC/VIC) data (Rodell et al, 2004), (d) ICESat-1 lake measurements (Zhang et al, , 2013, (e) one ALD model (Oelke and Zhang, 2007;Erkan et al, 2011) and (f) ICE-6G_C(VM5a) model (Argus et al, 2014;Peltier et al, 2015). A, B, C and D denote positions of the hydrology signals, which will be compared to those when Gaussian filter is used (Fig.…”

Section: Sh Tws Changes and The Comparisons With Precipitation And Aimentioning

confidence: 98%

Groundwater storage changes in the Tibetan Plateau and adjacent areas revealed from GRACE satellite gravity data

Xiang

Wang

Steffen

et al. 2016

Earth and Planetary Science Letters

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Understanding groundwater storage (GWS) changes is vital to the utilization and control of water resources in the Tibetan Plateau. However, well level observations are rare in this big area, and reliable hydrology models including GWS are not available. We use hydro-geodesy to quantitate GWS changes in the Tibetan Plateau and surroundings from 2003 to 2009 using a combined analysis of satellite gravity and satellite altimetry data, hydrology models as well as a model of glacial isostatic adjustment (GIA). Release-5 GRACE gravity data are jointly used in a mascon fitting method to estimate the terrestrial water storage (TWS) changes during the period, from which the hydrology contributions and the GIA effects are effectively deducted to give the estimates of GWS changes for 12 selected regions of interest. The hydrology contributions are carefully calculated from glaciers and lakes by ICESat-1 satellite altimetry data, permafrost degradation by an Active-Layer Depth (ALD) model, soil moisture and snow water equivalent by multiple hydrology models, and the GIA effects are calculated with the new ICE-6G_C (VM5a) model. Taking into account the measurement errors and the variability of the models, the uncertainties are rigorously estimated for the TWS changes, the hydrology contributions (including GWS changes) and the GIA effect. For the first time, we show explicitly separated GWS changes in the Tibetan Plateau and adjacent areas except for those to the south of the Himalayas. We find increasing trend rates for eight basins: +2.46 ± 2.24 Gt/yr for the Jinsha River basin, +1.77 ± 2.09 Gt/yr for the Nujiang-Lancangjiang Rivers Source Region, +1.86 ± 1.69 Gt/yr for the Yangtze River Source Region, +1.14 ± 1.39 Gt/yr for the Yellow River Source Region, +1.52 ± 0.95 Gt/yr for the Qaidam basin, +1.66 ± 1.52 Gt/yr for the central Qiangtang Nature Reserve, +5.37 ± 2.17 Gt/yr for the Upper Indus basin and +2.77 ± 0.99 Gt/yr for the Aksu River basin. All these increasing trends are most likely caused by increased runoff recharges from melt water and/or precipitation in the surroundings. We also find that the administrative actions such as the Chinese Ecological Protection and Construction Project help to store more groundwater in the Three Rivers Source Region, and suggest that seepages from the Endorheic basin to the west of it are a possible source for GWS increase in this region. In addition, our estimates for GWS changes basically confirm previous results along Afghanistan, Pakistan, north India and Bangladesh, and clearly reflect the excessive use of groundwater. Our results will benefit the water resource management in the study area, and are of particular significance for the ecological restoration in the Tibetan Plateau.

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Section: Sh Tws Changes and The Comparisons With Precipitation And Aimentioning

confidence: 98%

Groundwater storage changes in the Tibetan Plateau and adjacent areas revealed from GRACE satellite gravity data

Xiang

Wang

Steffen

et al. 2016

Earth and Planetary Science Letters

Self Cite

136

118

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“…Permafrost degradation due to increasing active-layer thickness has occurred in the TP, but the observations have mainly been made along the Qinghai-Tibet railroad (Luo et al, 2016;Wu et al, 2014;Yang et al, 2010). Based on regional modeling of the active-layer depth over the TP, a rough estimate of the amount of water released from permafrost degradation can be made (Erkan et al, 2011;Oelke and Zhang, 2007;Xiang et al, 2016). In addition, the contribution of melting ground ice to the surface water stream in the source area of the Yellow River, in the northeast TP, has been estimated at 13.2−16.7% by hydrological separation from a stable isotopic method (Yang et al, 2019).…”

Section: Lake Water Balancementioning

confidence: 99%

Response of Tibetan Plateau lakes to climate change: Trends, patterns, and mechanisms

Zhang

Yao

Xie

et al. 2020

Earth-Science Reviews

293

194

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“…A regional modeling of active-layer depth (ALD) over the TP has been performed for 1980-2001[Oelke and Zhang, 2007. The ALD data in the Inner TP were extracted from previous studies [Erkan et al, 2011;Oelke and Zhang, 2007]. Part of the meltwater from permafrost degradation may be stored as ground ice in the active layer; the released water is estimated using the model from Xiang et al [2016].…”

Section: Permafrostmentioning

confidence: 99%

Lake volume and groundwater storage variations in Tibetan Plateau's endorheic basin

Zhang

Yao

Shum

et al. 2017

Geophysical Research Letters

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The Tibetan Plateau (TP), the highest and largest plateau in the world, with complex and competing cryospheric‐hydrologic‐geodynamic processes, is particularly sensitive to anthropogenic warming. The quantitative water mass budget in the TP is poorly known. Here we examine annual changes in lake area, level, and volume during 1970s–2015. We find that a complex pattern of lake volume changes during 1970s–2015: a slight decrease of −2.78 Gt yr−1 during 1970s–1995, followed by a rapid increase of 12.53 Gt yr−1 during 1996–2010, and then a recent deceleration (1.46 Gt yr−1) during 2011–2015. We then estimated the recent water mass budget for the Inner TP, 2003–2009, including changes in terrestrial water storage, lake volume, glacier mass, snow water equivalent (SWE), soil moisture, and permafrost. The dominant components of water mass budget, namely, changes in lake volume (7.72 ± 0.63 Gt yr−1) and groundwater storage (5.01 ± 1.59 Gt yr−1), increased at similar rates. We find that increased net precipitation contributes the majority of water supply (74%) for the lake volume increase, followed by glacier mass loss (13%), and ground ice melt due to permafrost degradation (12%). Other term such as SWE (1%) makes a relatively small contribution. These results suggest that the hydrologic cycle in the TP has intensified remarkably during recent decades.

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Geodetic Constraints on the Qinghai-Tibetan Plateau Present-Day Geophysical Processes

Cited by 11 publications

References 42 publications

Groundwater storage changes in the Tibetan Plateau and adjacent areas revealed from GRACE satellite gravity data

Groundwater storage changes in the Tibetan Plateau and adjacent areas revealed from GRACE satellite gravity data

Response of Tibetan Plateau lakes to climate change: Trends, patterns, and mechanisms

Lake volume and groundwater storage variations in Tibetan Plateau's endorheic basin

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