Litcius/Paper detail

Snowfall-albedo feedbacks could have led to deglaciation of snowball Earth starting from mid-latitudes

Philipp de Vrese, Tobias Stacke, Jeremy K. Caves Rugenstein, Jason Goodman, Victor Brovkin

2021Communications Earth & Environment25 citationsDOIOpen Access PDF

Abstract

Abstract Simple and complex climate models suggest a hard snowball – a completely ice-covered planet – is one of the steady-states of Earth’s climate. However, a seemingly insurmountable challenge to the hard-snowball hypothesis lies in the difficulty in explaining how the planet could have exited the glaciated state within a realistic range of atmospheric carbon dioxide concentrations. Here, we use simulations with the Earth system model MPI-ESM to demonstrate that terminal deglaciation could have been triggered by high dust deposition fluxes. In these simulations, deglaciation is not initiated in the tropics, where a strong hydrological cycle constantly regenerates fresh snow at the surface, which limits the dust accumulation and snow aging, resulting in a high surface albedo. Instead, comparatively low precipitation rates in the mid-latitudes in combination with high maximum temperatures facilitate lower albedos and snow dynamics that – for extreme dust fluxes – trigger deglaciation even at present-day carbon dioxide levels.

Topics & Concepts

DeglaciationSnowball EarthAlbedo (alchemy)SnowAtmospheric sciencesEnvironmental scienceClimate stateClimatologyClimate modelEarth system sciencePrecipitationCarbon dioxide in Earth's atmosphereGeologyClimate changeGlobal warmingGlacial periodMeteorologyOceanographyGeographyEffects of global warmingPerformance artGeomorphologyArt historyArtCryospheric studies and observationsGeology and Paleoclimatology ResearchPolar Research and Ecology