Mass balances of Yala and Rikha Samba glaciers, Nepal, from 2000 to 2017

Stumm, D.; Joshi, Srijana; Gurung, Tika Ram; Silwal, Gunjan

doi:10.5194/essd-13-3791-2021

Cited by 15 publications

(30 citation statements)

References 101 publications

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“…In contrast to this, the small Nepalese glacier (Yala) was much less sensitive to the wetter conditions at the start of the Millennium, resulting in a more continuous mass loss (figure 3), consistent with modelled long term mass balances in northwestern Nepal (Arndt et al 2021). Although the size of the glacier and its limited accumulation area (Stumm et al 2021, Sunako et al 2020 may have dictated its reduced sensitivity to the expansion of the monsoon period, an early monsoon actually produces less snowfall during the monsoon transition period (May-June) at this glacier, despite shifting the occurrence of snow sooner. A weakening monsoon intensity and drier conditions, coinciding with warmer air temperatures of recent decades (figure 2) can explain half of the mass balance variability at this glacier, but the amount of snowfall during late June is also of great importance (figure 6).…”

Section: Discussionsupporting

confidence: 71%

“…Yala Glacier (28.237 • N 85.619 • E) is a small, 1.5 km 2 glacier situated in Langtang Valley, Nepal which has been the subject of long-term mass balance campaigns (e.g. Fujita et al 1998, Baral et al 2014, Stumm et al 2021, Sunako et al 2020 as well as the focus of research on energy balance and surface processes (Stigter et al 2018, Litt et al 2019. Parlung Glacier Number 4 (29.245 • N 96.928 • E, hereafter 'Parlung 4' or 'PAR4') is a 11.7 km 2 , spring-type accumulation glacier in the southeastern Tibetan Plateau.…”

Section: Study Areamentioning

confidence: 99%

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Multi-decadal monsoon characteristics and glacier response in High Mountain Asia

Shaw

Miles

Chen

et al. 2022

Environ. Res. Lett.

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Glacier health across High Mountain Asia (HMA) is highly heterogeneous and strongly governed by regional climate, which is variably influenced by monsoon dynamics and the westerlies. We explore four decades of glacier energy and mass balance at three climatically distinct sites across HMA by utilising a detailed land surface model driven by bias-corrected Weather Research and Forecasting (WRF) meteorological forcing. All three glaciers have experienced long-term mass losses (ranging from -0.04$\pm$0.09 to -0.59$\pm$0.20 m w. e. a$^{-1}$) consistent with widespread warming across the region. However, complex and contrasting responses of glacier energy and mass balance to the patterns of the Indian Summer Monsoon were evident, largely driven by the role snowfall timing, amount and phase. A later monsoon onset generates less total snowfall to the glacier in the southeastern Tibetan Plateau during May-June, augmenting net shortwave radiation and affecting annual mass balance (-0.5 m w.e. on average compared to early onset years). Conversely, timing of the monsoon's arrival has limited impact for the Nepalese Himalaya which is more strongly governed by the temperature and snowfall amount during the core monsoon season. In the arid central Tibetan Plateau, a later monsoon arrival results in a 40 mm (58\%) increase of May-June snowfall on average compared to early onset years, likely driven by the greater interaction of westerly storm events. Meanwhile,a late monsoon cessation at this site sees an average 200 mm (192\%) increase in late summer precipitation due to monsoonal storms. A trend toward weaker intensity monsoon conditions in recent decades, combined with long-term warming patterns, has produced predominantly negative glacier mass balances for all sites (up to 1 m w.e. more mass loss in the Nepalese Himalaya compared to strong monsoon intensity years) but sub-regional variability in monsoon timing can additionally complicate this response.

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Section: Discussionsupporting

confidence: 71%

Section: Study Areamentioning

confidence: 99%

Multi-decadal monsoon characteristics and glacier response in High Mountain Asia

Shaw

Miles

Chen

et al. 2022

Environ. Res. Lett.

View full text Add to dashboard Cite

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“…Fujita and Nuimura, 2011; Sugiyama and others, 2013). Acharya and Kayastha (2019) conducted in situ mass balance measurements for the 2011–2017 period, and Stumm and others (2021) updated a mass loss value of −0.80 ± 0.28 m water equivalent (w.e.) a −1 , with a mean equilibrium line altitude of 5456 m a.s.l.…”

Section: Study Site Data and Methodologymentioning

confidence: 99%

“…However, in situ observational studies remain scarce due to the remoteness of these glaciers and the associated logistical difficulties (e.g. Yao and others, 2012; Azam and others, 2016; Sherpa and others, 2017; Sunako and others, 2019; Angchuk and others, 2021; Stumm and others, 2021). Previous studies have employed global positioning system (GPS) and/or rangefinders during repeated surveys to derive point-based DEMs and capture surface elevation changes, and therefore estimate geodetic glacier mass balances (e.g.…”

Section: Introductionmentioning

confidence: 99%

Up-glacier propagation of surface lowering of Yala Glacier, Langtang Valley, Nepal Himalaya

et al. 2023

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We quantify the surface elevation changes along Yala Glacier in Langtang Valley, Nepal Himalaya, since 1981 using geodetic methods to understand the recent evolution and current state of small debris-free glaciers across the region. We analyse differential global positioning system measurements and aerial stereo imagery that were acquired along Yala Glacier in 2007, 2009, 2012 and 2015 to generate digital elevation models for each calculation period. Continuous surface lowering has mainly been observed across the down-glacier area during the calculation periods, although a large degree of variability exists, with this lowering trend propagating up-glacier in recent years. The area-weighted glacier mass balances range from −0.98 ± 0.27 to −0.26 ± 0.30 m w.e. a−1 for the five calculation periods (1981–2007, 2007–2009, 2009–2012, 2012–2015 and 2007–2015). These calculated mass-balance data reveal that Yala Glacier has undergone accelerated mass loss since the late 2000s, which is consistent with the results of previous in situ measurement and remote-sensing studies.

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“…In situ glacier-wide mass balance (MB) monitoring of glaciers provides an understanding of the quick response of the glaciers to local meteorological conditions (Oerlemans, 2001). Several in situ glaciological studies are being conducted over the different basins of the Himalaya (Dobhal et al, 2013;Mandal et al, 2020;Wagnon et al, 2021;Stumm et al, 2021) but these observations are still sparser compared to the other glacierized regions of the world (Zemp et al, 2015;Azam et al, 2018). Due to the harsh climatic conditions, low oxygen level, and steep terrain of the Himalaya, the in situ MBs have only been observed for a short period and on a few small glaciers (Azam et al, 2018).…”

mentioning

confidence: 99%

Positive mass budgets of high-altitude and debris-covered fragmented tributary glaciers in Gangotri Glacier System, Himalaya

et al. 2022

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Glacier-wide mass balances (MBs) of the Gangotri, Chaturangi, Raktavaran, Meru, and Gangotri Glacier System are reconstructed with a temperature-index (T-index) model using bias-corrected ERA5 data at a daily temporal resolution over 1979–2020. The model output is calibrated against available geodetic MB for Gangotri Glacier System and validated with satellite-derived snow line altitudes (SLAs) for Gangotri Glacier. Gangotri and Meru glaciers show mean mass wastage of –0.88 ± 0.31 m w. e. a‒ˡ (meter water equivalent per year) and ‒0.17 ± 0.29 m w. e. a‒ˡ, respectively whereas the mass budgets of fragmented tributary Chaturangi and Raktavaran glaciers are positive with the mean values of 0.49 ± 0.17 m w. e. a‒ˡ and 0.62 ± 0.15 m w. e. a‒ˡ, respectively over 1979–2020. Gangotri Glacier’s tongue is covered by thick debris having several supra-glacial lakes and ice cliffs (considered as melting hotspots); therefore, despite the presence of thick debris, we assume the melting over this area as of a clean glacier. The whole Gangotri Glacier System shows a moderate wastage of ‒0.27 ± 0.25 m w. e. a‒ˡ. The positive MBs of the Raktavaran and Chaturangi glaciers are due to their high area-elevation distribution and heavily debris-covered tongues. The positive MBs on these fragmented tributary glaciers are due to non-climatic topographic reasons and should not be misunderstood as climate change deniers or compared with Karakoram Anomaly. Modelled MBs are most sensitive to the threshold temperature for melt. The altitudinal MB sensitivities to all model parameters become negligible above 6,200 m a.s.l.

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Mass balances of Yala and Rikha Samba glaciers, Nepal, from 2000 to 2017

Cited by 15 publications

References 101 publications

Multi-decadal monsoon characteristics and glacier response in High Mountain Asia

Multi-decadal monsoon characteristics and glacier response in High Mountain Asia

Up-glacier propagation of surface lowering of Yala Glacier, Langtang Valley, Nepal Himalaya

Positive mass budgets of high-altitude and debris-covered fragmented tributary glaciers in Gangotri Glacier System, Himalaya

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