Archana Dayal scite author profile

Abstract. Melting of the Greenland Ice Sheet (GrIS) is the largest single contributor to eustatic sea level and is amplified by the growth of pigmented algae on the ice surface, which increases solar radiation absorption. This biological albedo-reducing effect and its impact upon sea level rise has not previously been quantified. Here, we combine field spectroscopy with a radiative-transfer model, supervised classification of unmanned aerial vehicle (UAV) and satellite remote-sensing data, and runoff modelling to calculate biologically driven ice surface ablation. We demonstrate that algal growth led to an additional 4.4–6.0 Gt of runoff from bare ice in the south-western sector of the GrIS in summer 2017, representing 10 %–13 % of the total. In localized patches with high biomass accumulation, algae accelerated melting by up to 26.15±3.77 % (standard error, SE). The year 2017 was a high-albedo year, so we also extended our analysis to the particularly low-albedo 2016 melt season. The runoff from the south-western bare-ice zone attributed to algae was much higher in 2016 at 8.8–12.2 Gt, although the proportion of the total runoff contributed by algae was similar at 9 %–13 %. Across a 10 000 km2 area around our field site, algae covered similar proportions of the exposed bare ice zone in both years (57.99 % in 2016 and 58.89 % in 2017), but more of the algal ice was classed as “high biomass” in 2016 (8.35 %) than 2017 (2.54 %). This interannual comparison demonstrates a positive feedback where more widespread, higher-biomass algal blooms are expected to form in high-melt years where the winter snowpack retreats further and earlier, providing a larger area for bloom development and also enhancing the provision of nutrients and liquid water liberated from melting ice. Our analysis confirms the importance of this biological albedo feedback and that its omission from predictive models leads to the systematic underestimation of Greenland's future sea level contribution, especially because both the bare-ice zones available for algal colonization and the length of the biological growth season are set to expand in the future.

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Glacier algae accelerate melt rates on the western Greenland Ice Sheet

Cook¹,

Tedstone²,

Williamson³

et al. 2019

Preprint

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Abstract. Melting of the Greenland Ice Sheet (GrIS) is the largest single contributor to eustatic sea level and is amplified by the growth of pigmented algae on the ice surface that increase solar radiation absorption. This biological albedo reducing effect and its impact upon sea level rise has not previously been quantified. Here, we combine field spectroscopy with a novel radiative transfer model, supervised classification of UAV and satellite remote sensing data and runoff modelling to calculate biologically-driven ice surface ablation and compare it to the albedo reducing effects of local mineral dust. We demonstrate that algal growth led to an additional 5.5–8.0 Gt of runoff from the western sector of the GrIS in summer 2016, representing 6–9 % of the total. Our analysis confirms the importance of the biological albedo feedback and that its omission from predictive models leads to the systematic underestimation of Greenland’s future sea level contribution, especially because both the bare ice zones available for algal colonization and the length of the active growth season are set to expand in the future.

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Seasonal snowpack microbial ecology and biogeochemistry on a High Arctic ice cap reveals negligible autotrophic activity during spring and summer melt

Dayal¹,

Hodson

Šabacká

et al. 2022

Preprint

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Nutrients delivered by snow from marine and continental sources were supplemented by the dissolution of dust deposited from local sources • Autotrophic communities were conspicuous by their absence within a High Arctic glacial snowpack during summer • Secondary bacterial production therefore dominated the entire summer • A superimposed ice layer of refrozen snowmelt acted as a temporary dilute store for nutrients and cells

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Marked Seasonal Changes in the Microbial Production, Community Composition, and Biogeochemistry of Glacial Snowpack Ecosystems in the Maritime Antarctic

et al. 2021

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 Regional nutrient enrichment by marine fauna influences the microbial ecology of glacial snowpacks in the maritime Antarctic during summer. Cold summers with low melt and frequent snowfall reduce photosynthesis at the surface and allow bacterial production to dominate. Persistent moisture supply to penguin guano enhances the effects of ammonium and organic acid deposition onto the snow ecosystem.

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Supplementary material to "Glacier algae accelerate melt rates on the western Greenland Ice Sheet"

Cook¹,

Tedstone²,

Williamson³

et al. 2019

Preprint

View full text Add to dashboard Cite

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Archana Dayal

Glacier algae accelerate melt rates on the south-western Greenland Ice Sheet

Glacier algae accelerate melt rates on the western Greenland Ice Sheet

Seasonal snowpack microbial ecology and biogeochemistry on a High Arctic ice cap reveals negligible autotrophic activity during spring and summer melt

Marked Seasonal Changes in the Microbial Production, Community Composition, and Biogeochemistry of Glacial Snowpack Ecosystems in the Maritime Antarctic

Supplementary material to "Glacier algae accelerate melt rates on the western Greenland Ice Sheet"

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Archana Dayal

Glacier algae accelerate melt rates on the south-western Greenland Ice Sheet

Glacier algae accelerate melt rates on the western Greenland Ice Sheet

Seasonal snowpack microbial ecology and biogeochemistry on a High Arctic ice cap reveals negligible autotrophic activity during spring and summer melt

Marked Seasonal Changes in the Microbial Production, Community Composition, and Biogeochemistry of Glacial Snowpack Ecosystems in the Maritime Antarctic

Supplementary material to &quot;Glacier algae accelerate melt rates on the western Greenland Ice Sheet&quot;

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Supplementary material to "Glacier algae accelerate melt rates on the western Greenland Ice Sheet"