JGR Paper: Modelling bioalbedo of snow

Online Early version here (copyedited version soon).

The ‘bioalbedo effect’ is the enhanced melting of snow and ice due to living organisms growing on it. Life can change the colour of the snow or ice, increasing its efficiency as an absorber of solar energy. Our new paper in Journal of Geophysical Research uses a modelling approach to examine this process for algal cells growing on snow.

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Red snow algae in Antarctica (ph. Andy Hodson)

 

The model can be broken down into distinct parts. The first part is a mixing model for pigments that can be present in snow algal cells. The user can define the relative amounts of each pigment in the cells. The cell wall is assumed to be transparent. This then allows the absorption coefficient for each individual algal cell to be calculated.

The second part of the model scatters these cells in a layer of a hypothetical snow pack. The layer can be any thickness and does not necessarily have to be the surface layer. The amount of algae is expressed by the user in g(algae)/g(snow). The radiative transfer model TARTES has been adapted to account for our algal cells and is used to predict the bihemispheric spectral reflectance of the surface.

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Example model output (extracted from Figure 3 in the paper) showing spectral albedo (G) and broadband albedo (H) with increasing concentration of primary carotenoids in 1mg(algae)/g (snow)

The albedo of the snow is then calculated using incoming solar radiation (measured or modelled, e.g. using NASA’s COART model). This can be plotted and analysed, or used to drive an energy balance model to determine how much the algae influence snow melt.

The paper shows that algae have the potential to reduce snow albedo, with the magnitude of their effect dependent upon how much algae is in the snow and how pigmented it is. It also shows that specific wavelengths of light are affected more than others by algal cells and that this could be used diagnostically, perhaps allowing us to detect algae from planes, drones or satellites. The energy balance part of the model shows that this affects how quickly the snow melts. A physical mechanism for algal acceleration of snow melt is thereby developed.

Next, we intend to develop a more sophisticated physical model that it is applicable to melting glacier ice as well as snow. This will help us to explain the mysterious ‘dark zone’ on the Greenland ice sheet which is probably discolored by a combination of dust, black carbon soots and algal blooms.

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At work on heavily discolored ice in the ‘dark zone’ on the Greenland Ice Sheet in 2010