Recent ground thermo-hydrological changes in a Tibetan endorheic catchment and implications for lake level changes

Martin, Léo; Westermann, Sebastian; Magni, Michele; Brun, Fanny; Fiddes, Joel; Lei, Yajie; Kraaijenbrink, Philip; Mathys, Tamara; Langer, Moritz; Allen, S. J.; Immerzeel, Walter W.

doi:10.5194/hess-2022-241

Cited by 2 publications

(1 citation statement)

References 72 publications

(117 reference statements)

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“…A 3‐D statistical downscaling method was used to produce T a and airP via solving the lapse rate based on the pressure‐level data sets. The downscaling scheme has been successfully applied in the complex terrain, that is, the Alps (Fiddes et al., 2015; Fiddes & Gruber, 2014) and the Tibetan Plateau (Cao et al., 2017; Martin et al., 2023).…”

Section: Methodsmentioning

confidence: 99%

Consistent Ground Surface Temperature Climatology Over China: 1956–2022

Wang,

Cao,

Hao

et al. 2024

JGR Atmospheres

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The ground surface represents the land‐atmosphere interface and plays a crucial role in exchanging energy, matter, and biochemical fluxes. The ground surface temperature (Ts) is hence widely investigated as an indicator to understand the thermal state of soil in a warming world. However, regular and continuous Ts measurements are rare worldwide, and the early Ts records were derived from snow surface measurements and are not comparable with the measurements of modern automatic systems. In this study, we reconstruct the Ts records of the China Meteorological Administration (CMA) for 1956–2022 by numerical simulation. The results show that the mean annual ground surface temperature (MAGST) during 1981–2010 ranged from 0.4 to 30.8°C at 632 stations. The MAGST was mainly controlled by air temperature and refined by snow depth. The overall MAGST increased by 0.20 ± 0.02°C dec−1 across China during 1956–2022 and showed pronounced interdecadal variability corresponding to the surface air temperature (0.23 ± 0.03°C dec−1). At the snow‐covered sites, the Ts warming was amplified by increased snow depth, leading to about 0.24°C dec−1 (or 70.6%) faster warming for Ts in winter compared to that of surface air temperature. Many of the early reported ground surface temperature studies based on CMA measurements did not consider the measurement inconsistency and likely overestimated the warming trend of ground surface temperature over China.

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Section: Methodsmentioning

confidence: 99%

Consistent Ground Surface Temperature Climatology Over China: 1956–2022

Wang,

Cao,

Hao

et al. 2024

JGR Atmospheres

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Recent ground thermo-hydrological changes in a southern Tibetan endorheic catchment and implications for lake level changes

Martin,

Westermann,

Magni

et al. 2023

Hydrol. Earth Syst. Sci.

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Abstract. Climate change modifies the water and energy fluxes between the atmosphere and the surface in mountainous regions such as the Qinghai–Tibet Plateau (QTP), which has shown substantial hydrological changes over the last decades, including rapid lake level variations. The ground across the QTP hosts either permafrost or is seasonally frozen, and, in this environment, the ground thermal regime influences liquid water availability, evaporation and runoff. Consequently, climate-induced changes in the ground thermal regime may contribute to variations in lake levels, but the validity of this hypothesis has yet to be established. This study focuses on the cryo-hydrology of the catchment of Lake Paiku (southern Tibet) for the 1980–2019 period. We process ERA5 data with downscaling and clustering tools (TopoSCALE, TopoSUB) to account for the spatial variability of the climate in our forcing data (Fiddes and Gruber, 2012, 2014). We use a distributed setup of the CryoGrid community model (version 1.0) to quantify thermo-hydrological changes in the ground during this period. Forcing data and simulation outputs are validated with data from a weather station, surface temperature loggers and observations of lake level variations. Our lake budget reconstruction shows that the main water input to the lake is direct precipitation (310 mm yr−1), followed by glacier runoff (280 mm yr−1) and land runoff (180 mm yr−1). However, altogether these components do not offset evaporation (860 mm yr−1). Our results show that both seasonal frozen ground and permafrost have warmed (0.17 ∘C per decade 2 m deep), increasing the availability of liquid water in the ground and the duration of seasonal thaw. Correlations with annual values suggest that both phenomena promote evaporation and runoff. Yet, ground warming drives a strong increase in subsurface runoff so that the runoff/(evaporation + runoff) ratio increases over time. This increase likely contributed to stabilizing the lake level decrease after 2010. Summer evaporation is an important energy sink, and we find active-layer deepening only where evaporation is limited. The presence of permafrost is found to promote evaporation at the expense of runoff, consistently with recent studies suggesting that a shallow active layer maintains higher water contents close to the surface. However, this relationship seems to be climate dependent, and we show that a colder and wetter climate produces the opposite effect. Although the present study was performed at the catchment scale, we suggest that this ambivalent influence of permafrost may help to understand the contrasting lake level variations observed between the south and north of the QTP, opening new perspectives for future investigations.

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Recent ground thermo-hydrological changes in a Tibetan endorheic catchment and implications for lake level changes

Cited by 2 publications

References 72 publications

Consistent Ground Surface Temperature Climatology Over China: 1956–2022

Consistent Ground Surface Temperature Climatology Over China: 1956–2022

Recent ground thermo-hydrological changes in a southern Tibetan endorheic catchment and implications for lake level changes

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