Spectral characterization, radiative forcing and pigment content of coastal Antarctic snow algae: approaches to spectrally discriminate red and green communities and their impact on snowmelt
Abstract
Here, we present radiative forcing (RF) estimates by snow algae in the Antarctic Peninsula (AP) region from multi-year measurements of solar radiation and ground-based hyperspectral characterization of red and green snow algae collected during a brief field expedition in austral summer 2018. Our analysis includes pigment content from samples at three bloom sites. Algal biomass in the snow and albedo reduction are well-correlated across the visible spectrum. Relative to clean snow, visibly green patches reduce snow albedo by similar to 40 % and red patches by similar to 20 %. However, red communities absorb considerably more light per milligram of pigment compared to green communities, particularly in green wavelengths. Based on our study results, it should be possible to differentiate red and green algae using Sentinel-2 bands in blue, green and red wavelengths. Instantaneous RF averages were double for green (180 W m(-2)) vs. red communities (88 W m(-2)), with a maximum of 228 W m(-2). Based on multi-year solar radiation measurements at Palmer Station, this translated to a mean daily RF of similar to 26 W m(-2) (green) and similar to 13 W m(-2) (red) during peak growing season - on par with midlatitude dust attributions capable of advancing snowmelt. This results in similar to 2522 m(3) of snow melted by green-colored algae and similar to 1218 m(3) of snow melted by red-colored algae annually over the summer, suggesting snow algae play a significant role in snowmelt in the AP regions where they occur. We suggest impacts of RF by snow algae on snowmelt be accounted for in future estimates of Antarctic ice-free expansion in the AP region.
Más información
Título según WOS: | Spectral characterization, radiative forcing and pigment content of coastal Antarctic snow algae: approaches to spectrally discriminate red and green communities and their impact on snowmelt |
Título de la Revista: | CRYOSPHERE |
Volumen: | 15 |
Número: | 1 |
Editorial: | Copernicus Gesellschaft mbH |
Fecha de publicación: | 2021 |
Página de inicio: | 133 |
Página final: | 148 |
DOI: |
10.5194/TC-15-133-2021 |
Notas: | ISI |