Meteorological impacts of a novel debris‐covered glacier category in a regional climate model across a Himalayan catchment

Potter, Emily; Orr, Andrew; Willis, Ian; Bannister, Daniel; Wagnon, Patrick

doi:10.1002/asl.1018

Cited by 6 publications

(8 citation statements)

References 28 publications

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“…Overall, the model manages to simulate the diurnal cycle of the winds that was evident in the observations. The along-valley wind characteristics in Khumbu Valley were found to be similar to what previous research has shown, with respect to both observational (Inoue, 1976;Ueno and Kayastha, 2001;Bollasina et al, 2002;Ueno et al, 2008;Bonasoni et al, 2010;Shea et al, 2015) and model-based studies (Potter et al, 2018(Potter et al, , 2021.…”

Section: Discussionsupporting

confidence: 87%

“…This study concentrates on four valleys located in the Nepal Himalayas during a 4 d period in December 2014. The local wind patterns in Khumbu Valley (one of the valleys that is investigated in this study) have been studied in the past by means of meteorological observations (Inoue, 1976;Ueno and Kayastha, 2001;Bollasina et al, 2002;Ueno et al, 2008;Bonasoni et al, 2010;Shea et al, 2015;Yang et al, 2018) and high-resolution meteorological modelling (Karki et al, 2017;Potter et al, 2018Potter et al, , 2021. Overall, the daily cycle of the along-valley winds in Khumbu Valley are simi-lar among existing studies, with well-defined daytime upvalley winds and weaker night-time winds flowing either in the up-or down-valley direction.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Daytime along-valley winds in the Himalayas as simulated by the Weather Research and Forecasting (WRF) model

Mikkola

Sinclair²,

Bister³

et al. 2023

Atmos. Chem. Phys.

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Abstract. Local along-valley winds in four major valleys on the southern slope of the Nepal Himalayas are studied by means of high-resolution meteorological modelling. The Weather Research and Forecasting model is run with a 1 km horizontal grid spacing covering a 4 d period in December 2014. Model evaluation against meteorological observations from three automatic weather stations in the Khumbu Valley (one of the four valleys) shows a good agreement between the modelled and observed daily cycle of the near-surface wind speed and direction. Well-defined daytime up-valley winds are found in all of the four valleys during this 4 d period. The night-time along-valley winds are weak in magnitude and flow mostly in the up-valley direction. Differences in the daytime up-valley winds are found between the valleys and their parts. As the valleys are under similar large-scale forcing, the differences are assumed to be due to differences in the valley topographies. Parts of the valleys with a steep valley floor inclination (2–5∘) are associated with weaker and shallower daytime up-valley winds compared with the parts that have nearly flat valley floors (<1∘). In the four valleys, the ridge heights also increase along the valley, meaning that the valley floor inclination does not necessarily lead to a reduction in the volume of the valley atmosphere. This way, the dominant driving mechanism of the along-valley winds, within the valleys, could shift from the valley volume effect to buoyant forcing due to the inclination. Two of the valleys have a 1 km high barrier in their entrances between the valley and the plain. Winds at the valley entrances of these two valleys are weaker compared with the open valley entrances. Strong and shallow winds, resembling down-slope winds, are found on the leeward slope of the barrier followed by weaker and deeper winds at the valley entrance, 20 km towards the valley from the barrier. Although the large-scale flow during the 4 d period was similar to the long-term climatology, the impact of different large-scale flows on the thermally driven winds was not considered. This topic could be addressed in the future by performing a longer simulation.

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Section: Discussionsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Daytime along-valley winds in the Himalayas as simulated by the Weather Research and Forecasting (WRF) model

Mikkola

Sinclair²,

Bister³

et al. 2023

Atmos. Chem. Phys.

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“…Spatially distributed wind modeling is more challenging and involves complex relationships with respect to topography and thermal/dynamic atmospheric processes (Ayala et al, 2017;Potter et al, 2020). In this study, the wind pattern is spatialized using equations from the MicroMet model (Liston & Elder, 2006;Liston & Sturm, 1998):…”

Section: Spatialization Of Meteorological Datamentioning

confidence: 99%

“…Spatially distributed wind modeling is more challenging and involves complex relationships with respect to topography and thermal/dynamic atmospheric processes (Ayala et al., 2017; Potter et al., 2020). In this study, the wind pattern is spatialized using equations from the MicroMet model (Liston & Elder, 2006; Liston & Sturm, 1998):

u={u}_{AWS}\ast \frac{\left(1+{\gamma }_{s}{{\Omega }}_{s}+{\gamma }_{c}{{\Omega }}_{c}\right)}{\left(1+{\gamma }_{s}{{\Omega }}_{s(AWS)}+{\gamma }_{c}{{\Omega }}_{c(AWS)}\right)}

where u is the topographically modified wind speed, u AWS is the measured wind speed at the AWS site, Ω c the terrain curvature, and Ω s is the slope in the direction of the wind:

{{\Omega }}_{s}={S}_{t}\left({\theta }_{u}-{A}_{t}\right)

…”

Section: Location Data and Modelsmentioning

confidence: 99%

Quantifying Supraglacial Debris‐Related Melt‐Altering Effects on the Djankuat Glacier, Caucasus, Russian Federation

Verhaegen,

Rybak,

Popovnin

et al. 2024

JGR Earth Surface

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We use a spatially distributed and physically based energy and mass balance model to derive the Østrem curve, which expresses the supraglacial debris‐related relative melt alteration versus the debris thickness, for the Djankuat Glacier, Caucasus, Russian Federation. The model is driven by meteorological data from two on‐glacier weather stations and ERA‐5 Land reanalysis data. A direct pixel‐by‐pixel comparison of the melt rates obtained from both a clean ice and debris‐covered ice mass balance model results in the quantification of debris‐related relative melt‐modification ratios, capturing the degree of melt enhancement or suppression as a function of the debris thickness. The main results show that the distinct surface features and different surface temperature/moisture and near‐surface wind regimes that persist over debris‐covered ice significantly alter the pattern of the energy and mass fluxes when compared to clean ice. Consequently, a maximum relative melt enhancement of 1.36 is modeled on the glacier for thin/patchy debris with a thickness of 0.03 m. However, insulating effects suppress sub‐debris melt under debris layers thicker than a critical debris thickness of 0.09 m. Sensitivity experiments show that especially within‐debris properties, such as the thermal conductivity and the vertical debris porosity gradient, highly impact the magnitude of the sub‐debris melt rates. Our results also highlight the scale‐dependency as well as the dynamic nature of the debris thickness‐melt relationship for changing climatic conditions, which may have significant implications for the climate change response of debris‐covered glaciers.

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“…Studies employing distributed energy balance models could, for example, test the melt-equalizing effect of debris at the glacier scale and its overall effect on the catchment runoff. This could be combined with generating spatially consistent forcing data using high-resolution weather modelling as in Bonekamp et al (2019) or Potter et al (2020), and expanded to larger domains. Realistic representations of the glacier surface, including distributed debris thickness, and supraglacial features, such as ice cliffs and surface ponds, should also be established to provide well-constrained water budgets and improved representations of glacierised environments in land-surface models under present and future environmental conditions.…”

Section: Future Workmentioning

confidence: 99%

Understanding monsoon controls on the energy and mass balance of Himalayan glaciers

Fugger

Fyffe

Fatichi

et al. 2021

Preprint

Self Cite

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Abstract. The Indian and East Asian Summer Monsoons shape the melt and accumulation patterns of glaciers in High Mountain Asia in complex ways due to the interaction of persistent cloud cover, large temperature amplitudes, high atmospheric water content and high precipitation rates. While the monsoons dominate the climate of the southern and eastern regions, they progressively lose strength westward towards the Karakoram, where the influence of Westerlies is predominant. Despite the major role of the monsoon in the Himalayas, a holistic understanding of their influence on the region's glaciers is lacking because previous applications of energy- and mass-balance models have been limited to single study sites. In this study, we use a full energy- and mass-balance model and seven on-glacier automatic weather station datasets from different parts of the Himalayas to investigate how monsoon conditions influence the glacier surface energy and mass balance. In particular, we look at how debris-covered and debris-free glaciers respond differently to monsoonal conditions. The radiation budget mostly controls the melt of clean-ice glaciers, but turbulent fluxes also play an important role in modulating the melt energy on debris-covered glaciers. The sensible heat flux reduces during core monsoon, but the latent heat flux removes energy from the surface due to evaporation of liquid water. This interplay of radiative and turbulent fluxes, together with compensations between increasing and decreasing melt rates over the diurnal cycle, causes debris-covered glacier melt rates to stay almost constant over the entire ablation period through the different phases of the monsoon. Ice melt under thin debris, on the other hand, is amplified by both the dark surface albedo and the turbulent fluxes, which act as a source of energy through surface heating and condensation, especially during monsoon. Pre-monsoon snow cover can considerably delay melt onset and have a strong impact on the seasonal mass balance. Intermittent monsoon snow cover further modulates the melt rates at high elevation. Given our results, we expect the mass balance of debris-covered glaciers to react less sensitively to projected future monsoon conditions than clean-ice and dirty-ice glaciers. This work is fundamental to the understanding of the present and future Himalayan cryosphere and water budget evolution, while informing and motivating further glacier- and catchment-scale research using process-based models (Yang et al., 2017).

show abstract

Meteorological impacts of a novel debris‐covered glacier category in a regional climate model across a Himalayan catchment

Cited by 6 publications

References 28 publications

Daytime along-valley winds in the Himalayas as simulated by the Weather Research and Forecasting (WRF) model

Daytime along-valley winds in the Himalayas as simulated by the Weather Research and Forecasting (WRF) model

Quantifying Supraglacial Debris‐Related Melt‐Altering Effects on the Djankuat Glacier, Caucasus, Russian Federation

Understanding monsoon controls on the energy and mass balance of Himalayan glaciers

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