Project description
Modelling future melting through ice algae growth
Understanding of the stability of the Greenland ice sheet (GrIS) is essential for the security of coastal areas around the world since increased melting will lead to a rise in sea level. The GrIS is a vast ice area occupying roughly 80 % of the surface of Greenland. Scientists discovered that GrIS increasingly darkens during the melt season because of the rapid growth of glacier algae in the ice surface, resulting in a deep purple or black surface haze. The glacier algae also trap dust in the surface, which contributes to the darkening. The darkening causes the ice sheet to melt more quickly. The EU-funded Deep Purple project intends to establish the combination of factors which give rise to algal blooms. It will combine simultaneous studies of the biology, chemistry and physics of the melting surface ice to identify which process combinations cause algal blooms. This synergy is fundamental for understanding where current blooms occur, and for predicting the future occurrence of blooms in a warming world, where more of the ice sheet surface is melting.
Objective
The stability of the Greenland Ice Sheet (GrIS) is a threat to coastal communities worldwide. The PIs have changed our understanding of why it darkens during the melt season, becoming increasingly deep purple due to pigmented ice algal blooms in the ice surface, producing more melt and accelerating the GrIS towards its tipping point, and increasing sea level. The next step jump in our understanding of biological darkening will be provided by DEEP PURPLE, which will establish the factors that control ice algal blooms. These factors are essential for modelling of future melting, which require a process-based understanding of blooming. DEEP PURPLE will quantify the synergies between the biology, chemistry and physics of ice algae micro-niches in rotting, melting ice, and examine the combination of factors which stabilise them. State-of-the-science analytical and observational methods will be employed to characterise the complex mosaic of wet ice habitats, dependent on factors such as the hydrology, nutrient status, particulate content and light fields within these continually evolving ice-water-particulate-microbe systems. We will quantitatively assess why and how the fine light mineral dust particulates contained within the melting ice amplify the growth of ice algae. The particulate content and composition of different layers in the GrIS is dependent on age, and so the algae that the melting ice can support may fundamentally change over time. We look back to understand if the ice biome has changed through the Anthropocene via analyse of fjord sediments. The first draft genome of ice algae will show their key adaptations to glacier surface habitats. DEEP PURPLE looks forward by providing the critical field data sets and conceptual models of ice algal growth that will facilitate the next generation of predictive models of sea level rise due to biologically enhanced melting of the GrIS.
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Funding Scheme
ERC-SyG - Synergy grantHost institution
8000 Aarhus C
Denmark