Your search keyword '"McCarthy, Michael"' showing total 7 results

1. Local Controls on Near‐Surface Glacier Cooling Under Warm Atmospheric Conditions.

Author

Shaw, Thomas E., Buri, Pascal, McCarthy, Michael, Miles, Evan S., and Pellicciotti, Francesca

Subjects

ALPINE glaciers, WEATHER, GLACIERS, KATABATIC winds, CLIMATE extremes, BOUNDARY layer (Aerodynamics)

Abstract

The near‐surface boundary layer can mediate the response of mountain glaciers to external climate, cooling the overlying air and promoting a density‐driven glacier wind. The fundamental processes are conceptually well understood, though the magnitudes of cooling and presence of glacier winds are poorly quantified in space and time, increasing the forcing uncertainty for melt models. We utilize a new data set of on‐glacier meteorological measurements on three neighboring glaciers in the Swiss Alps to explore their distinct response to regional climate under the extreme 2022 summer. We find that synoptic wind origins and local terrain modifications, not only glacier size, play an important role in the ability of a glacier to cool the near‐surface air. Warm air intrusions from valley or synoptically‐driven winds onto the glacier can occur between ∼19% and 64% of the time and contribute between 3% and 81% of the total sensible heat flux to the surface during warm afternoon hours, depending on the fetch of the glacier flowline and its susceptibility to boundary layer erosion. In the context of extreme summer warmth, indicative of future conditions, the boundary layer cooling (up to 6.5°C cooler than its surroundings) and resultant katabatic wind flow are highly heterogeneous between the study glaciers, highlighting the complex and likely non‐linear response of glaciers to an uncertain future. Plain Language Summary: The presence of a 0°C ice surface cools the near‐surface air and generates a unique micro‐climate that complicates a glaciers response to future warming. Using a new data series on three glaciers during an extreme summer of 2022, we explore how variable this cooling is in space and time and investigate the factors that can control it. We focus largely on the role of valley and synoptic winds that are found to affect glaciers of varying size and orientation differently, influencing the amount of heat transfer to the ice surface that glaciers receive from outside its own micro‐climate. Moreover, we find that the presence of glacier winds can act to enhance or reduce overall heat transfer to the glacier, depending on the wind strength and degree of boundary layer disruption. We highlight the complexities that are ignored in simpler melt modeling frameworks and demonstrate how, especially under extreme summer heat, indicative of future conditions, static parameters to relate glacier melt to temperature are likely to be inappropriate. Key Points: Glacier size and alignment with valley/synoptic wind gradients control the magnitude of near‐surface coolingValley/synoptic winds can occur between 19% and 64% of the time and contribute between 3% and 81% of total sensible heat to the ice surfaceLocalized cooling and turbulence in the boundary layer increase the complexity and non‐linearity of glacier response to climate [ABSTRACT FROM AUTHOR]

Published

2024

2. Land Surface Modeling in the Himalayas: On the Importance of Evaporative Fluxes for the Water Balance of a High‐Elevation Catchment.

Author

Buri, Pascal, Fatichi, Simone, Shaw, Thomas E., Miles, Evan S., McCarthy, Michael J., Fyffe, Catriona L., Fugger, Stefan, Ren, Shaoting, Kneib, Marin, Jouberton, Achille, Steiner, Jakob, Fujita, Koji, and Pellicciotti, Francesca

Subjects

ALPINE glaciers, HYDROLOGIC cycle, WATER supply, SNOWMELT, PLANT transpiration, WATER transfer

Abstract

High Mountain Asia (HMA) is among the most vulnerable water towers globally and yet future projections of water availability in and from its high‐mountain catchments remain uncertain, as their hydrologic response to ongoing environmental changes is complex. Mechanistic modeling approaches incorporating cryospheric, hydrological, and vegetation processes in high spatial, temporal, and physical detail have never been applied for high‐elevation catchments of HMA. We use a land surface model at high spatial and temporal resolution (100 m and hourly) to simulate the coupled dynamics of energy, water, and vegetation for the 350 km2 Langtang catchment (Nepal). We compare our model outputs for one hydrological year against a large set of observations to gain insight into the partitioning of the water balance at the subseasonal scale and across elevation bands. During the simulated hydrological year, we find that evapotranspiration is a key component of the total water balance, as it causes about the equivalent of 20% of all the available precipitation or 154% of the water production from glacier melt in the basin to return directly to the atmosphere. The depletion of the cryospheric water budget is dominated by snow melt, but at high elevations is primarily dictated by snow and ice sublimation. Snow sublimation is the dominant vapor flux (49%) at the catchment scale, accounting for the equivalent of 11% of snowfall, 17% of snowmelt, and 75% of ice melt, respectively. We conclude that simulations should consider sublimation and other evaporative fluxes explicitly, as otherwise water balance estimates can be ill‐quantified. Plain Language Summary: The Himalayan mountains are a crucial source of water for local communities and the densely populated lowlands. Snow and glaciers are important for the water cycle in mountains, and many studies have focused on them. However, vegetation can play a central role, too. To better understand the water cycle in a high‐elevation Himalayan basin, we use a computer model that considers physical processes of snow and glaciers, soil, and vegetation in high detail. We simulate the catchment water balance and investigate the importance of single components at different elevations and in different seasons. We find that the transfer of water, in vapor form from the ground, snow and ice and the transpiration of plants are important for the water budget in the study basin, causing more water to return to the atmosphere than ice melt contributing to river runoff. Above 6,500 m above sea level, it is the transformation of snow into water vapor and below 4,000 m the transpiration from vegetation that dominate the water budget. We conclude that models simulating the water cycle in high mountain regions should consider vapor fluxes, as otherwise estimates of the water balance can be misleading. Key Points: Land surface modeling reveals high altitudinal/subseasonal variability in water balance partitioning in a glacierized Himalayan catchmentWater loss through evapotranspiration, dominated by snow sublimation, exceeds water production from glacier melt by 59% at catchment scaleDepletion of cryospheric water budget is dominated by snow melt, but at high elevations is primarily dictated by snow and ice sublimation [ABSTRACT FROM AUTHOR]

Published

2023

3. The Decaying Near‐Surface Boundary Layer of a Retreating Alpine Glacier.

Author

Shaw, Thomas E., Buri, Pascal, McCarthy, Michael, Miles, Evan S., Ayala, Álvaro, and Pellicciotti, Francesca

Subjects

ALPINE glaciers, BOUNDARY layer (Aerodynamics), GLOBAL warming, KATABATIC winds, CLIMATE sensitivity, GLACIAL melting

Abstract

The presence of a developed boundary layer decouples a glacier's response from ambient conditions, suggesting that sensitivity to climate change is increased by glacier retreat. To test this hypothesis, we explore six years of distributed meteorological data on a small Swiss glacier in the period 2001–2022. Large glacier fragmentation has occurred since 2001 (−35% area change up to 2022) coinciding with notable frontal retreat, an observed switch from down‐glacier katabatic to up‐glacier valley winds and an increased sensitivity (ratio) of on‐glacier to off‐glacier temperature. As the glacier ceases to develop density‐driven katabatic winds, sensible heat fluxes on the glacier are increasingly determined by the conditions occurring outside the boundary layer of the glacier, sealing the glacier's demise as the climate continues to warm and experience an increased frequency of extreme summers. Plain Language Summary: Down‐glacier winds promote a unique micro‐climate, maintaining relatively lower temperatures over the surface of mountain glaciers. Using six years of meteorological data in the period 2001–2022, we observe increases in the relative changes of above‐ice air temperatures compared to temperatures outside the glacier. As the glacier ceases to develop its own micro‐climate, warmer winds generated by heated valley slopes increasingly control the amount of heat transfer to melt glacier ice. This work offers new observational evidence that suggests that, as glaciers continue to shrink and fragment, they becoming increasingly sensitive to future climate warming. Key Points: On‐glacier air temperatures have become more sensitive to ambient temperatures in a warming climateUp‐valley winds have increased >20% between 2001 and 2021, making sensible heat fluxes more dependent on conditions outside the glacierThe decay of the katabatic system due to glacier retreat indicates a nonlinear sensitivity of the glacier to continued warming [ABSTRACT FROM AUTHOR]

Published

2023

4. Controls on Ice Cliff Distribution and Characteristics on Debris‐Covered Glaciers.

Author

Kneib, Marin, Fyffe, Catriona L., Miles, Evan S., Lindemann, Shayna, Shaw, Thomas E., Buri, Pascal, McCarthy, Michael, Ouvry, Boris, Vieli, Andreas, Sato, Yota, Kraaijenbrink, Philip D. A., Zhao, Chuanxi, Molnar, Peter, and Pellicciotti, Francesca

Subjects

ICE prevention & control, GLACIERS, CLIFFS, ALPINE glaciers, GLACIAL melting, HYDROLOGY

Abstract

Ice cliff distribution plays a major role in determining the melt of debris‐covered glaciers but its controls are largely unknown. We assembled a data set of 37,537 ice cliffs and determined their characteristics across 86 debris‐covered glaciers within High Mountain Asia (HMA). We find that 38.9% of the cliffs are stream‐influenced, 19.5% pond‐influenced and 19.7% are crevasse‐originated. Surface velocity is the main predictor of cliff distribution at both local and glacier scale, indicating its dependence on the dynamic state and hence evolution stage of debris‐covered glacier tongues. Supraglacial ponds contribute to maintaining cliffs in areas of thicker debris, but this is only possible if water accumulates at the surface. Overall, total cliff density decreases exponentially with debris thickness as soon as the debris layer reaches a thickness of over 10 cm. Plain Language Summary: Debris‐covered glaciers are common throughout the world's mountain ranges and are characterized by the presence of steep ice cliffs among the debris‐covered ice. It is well‐known that the cliffs are responsible for a large portion of the melt of these glaciers but the controls on their formation, development and distribution across glaciers remains poorly understood. Novel mapping approaches combined with high‐resolution satellite and drone products enabled us to disentangle some of these controls and to show that the ice cliffs are generally formed and maintained by the surface hydrology (ponds or streams) or by the opening of crevasses. As a result, they depend both at the local and glacier scale on the dynamic state of the glaciers as well as the evolution stage of their debris cover. This provides a pathway to better represent their contribution to glacier melt in predictive glacier models. Key Points: We derived an unprecedented data set of 37,537 ice cliffs and their characteristics across 86 debris‐covered glaciers in High Mountain AsiaWe find that 38.9% of the cliffs are stream‐influenced, 19.5% pond‐influenced and 19.7% are crevasse‐originatedIce cliff distribution can be predicted by velocity, as an indicator of the dynamics and state of evolution of debris‐covered glaciers [ABSTRACT FROM AUTHOR]

Published

2023

5. Sub-seasonal variability of supraglacial ice cliff melt rates and associated processes from time-lapse photogrammetry.

Author

Kneib, Marin, Miles, Evan S., Buri, Pascal, Fugger, Stefan, McCarthy, Michael, Shaw, Thomas E., Chuanxi, Zhao, Truffer, Martin, Westoby, Matthew J., Yang, Wei, and Pellicciotti, Francesca

Subjects

GLACIERS, CLIFFS, ALPINE glaciers, DIGITAL elevation models, LONG-Term Evolution (Telecommunications), MELTING

Abstract

Melt from supraglacial ice cliffs is an important contributor to the mass loss of debris-covered glaciers. However, ice cliff contribution is difficult to quantify as they are highly dynamic features, and the paucity of observations of melt rates and their variability leads to large modelling uncertainties. We quantify monsoon season melt and 3D evolution of four ice cliffs over two debris-covered glaciers in High Mountain Asia (Langtang Glacier, Nepal, and 24K Glacier, China) at very high resolution using terrestrial photogrammetry applied to imagery captured from time-lapse cameras installed on lateral moraines. We derive weekly flow-corrected digital elevation models (DEMs) of the glacier surface with a maximum vertical bias of ± 0.2 m for Langtang Glacier and ± 0.05 m for 24K Glacier and use change detection to determine distributed melt rates at the surfaces of the ice cliffs throughout the study period. We compare the measured melt patterns with those derived from a 3D energy balance model to derive the contribution of the main energy fluxes. We find that ice cliff melt varies considerably throughout the melt season, with maximum melt rates of 5 to 8 cm d -1 , and their average melt rates are 11–14 (Langtang) and 4.5 (24K) times higher than the surrounding debris-covered ice. Our results highlight the influence of redistributed supraglacial debris on cliff melt. At both sites, ice cliff albedo is influenced by the presence of thin debris at the ice cliff surface, which is largely controlled on 24K Glacier by liquid precipitation events that wash away this debris. Slightly thicker or patchy debris reduces melt by 1–3 cm d -1 at all sites. Ultimately, our observations show a strong spatio-temporal variability in cliff area at each site, which is controlled by supraglacial streams and ponds and englacial cavities that promote debris slope destabilisation and the lateral expansion of the cliffs. These findings highlight the need to better represent processes of debris redistribution in ice cliff models, to in turn improve estimates of ice cliff contribution to glacier melt and the long-term geomorphological evolution of debris-covered glacier surfaces. [ABSTRACT FROM AUTHOR]

Published

2022

6. Modelling supraglacial debris-cover evolution from the single-glacier to the regional scale: an application to High Mountain Asia.

Author

Compagno, Loris, Huss, Matthias, Miles, Evan Stewart, McCarthy, Michael James, Zekollari, Harry, Dehecq, Amaury, Pellicciotti, Francesca, and Farinotti, Daniel

Subjects

GLACIERS, ALPINE glaciers, FLOW velocity

Abstract

Currently, about 12 %–13 % of High Mountain Asia's glacier area is debris-covered, which alters its surface mass balance. However, in regional-scale modelling approaches, debris-covered glaciers are typically treated as clean-ice glaciers, leading to a bias when modelling their future evolution. Here, we present a new approach for modelling debris area and thickness evolution, applicable from single glaciers to the global scale. We derive a parameterization and implement it as a module into the Global Glacier Evolution Model (GloGEMflow), a combined mass-balance ice-flow model. The module is initialized with both glacier-specific observations of the debris' spatial distribution and estimates of debris thickness. These data sets account for the fact that debris can either enhance or reduce surface melt depending on thickness. Our model approach also enables representing the spatiotemporal evolution of debris extent and thickness. We calibrate and evaluate the module on a selected subset of glaciers and apply GloGEMflow using different climate scenarios to project the future evolution of all glaciers in High Mountain Asia until 2100. Explicitly accounting for debris cover has only a minor effect on the projected mass loss, which is in line with previous projections. Despite this small effect, we argue that the improved process representation is of added value when aiming at capturing intra-glacier scales, i.e. spatial mass-balance distribution. Depending on the climate scenario, the mean debris-cover fraction is expected to increase, while mean debris thickness is projected to show only minor changes, although large local thickening is expected. To isolate the influence of explicitly accounting for supraglacial debris cover, we re-compute glacier evolution without the debris-cover module. We show that glacier geometry, area, volume, and flow velocity evolve differently, especially at the level of individual glaciers. This highlights the importance of accounting for debris cover and its spatiotemporal evolution when projecting future glacier changes. [ABSTRACT FROM AUTHOR]

Published

2022

7. Understanding monsoon controls on the energy and mass balance of glaciers in the Central and Eastern Himalaya.

Author

Fugger, Stefan, Fyffe, Catriona L., Fatichi, Simone, Miles, Evan, McCarthy, Michael, Shaw, Thomas E., Ding, Baohong, Yang, Wei, Wagnon, Patrick, Immerzeel, Walter, Liu, Qiao, and Pellicciotti, Francesca

Subjects

MONSOONS, MASS budget (Geophysics), GLACIERS, AUTOMATIC meteorological stations, CLOUDINESS, EDDY flux, ALPINE glaciers, SNOW cover

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 ranges, high atmospheric water content and high precipitation rates. Glacier energy- and mass-balance modelling using in situ measurements offers insights into the ways in which surface processes are shaped by climatic regimes. 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 Central and Eastern Himalaya 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 primarily controls the melt of clean-ice glaciers, but turbulent fluxes play an important role in modulating the melt energy on debris-covered glaciers. The sensible heat flux decreases during core monsoon, but the latent heat flux cools the surface due to evaporation of liquid water. This interplay of radiative and turbulent fluxes causes debris-covered glacier melt rates to stay almost constant through the different phases of the monsoon. Ice melt under thin debris, on the other hand, is amplified by both the dark surface and the turbulent fluxes, which intensify melt during monsoon through surface heating and condensation. Pre-monsoon snow cover can considerably delay melt onset and have a strong impact on the seasonal mass balance. Intermittent monsoon snow cover lowers the melt rates at high elevation. This work is fundamental to the understanding of the present and future Himalayan cryosphere and water budget, while informing and motivating further glacier- and catchment-scale research using process-based models. [ABSTRACT FROM AUTHOR]

Published

2022