Abstract
The Antarctic Peninsula experiences a fast retreat of glaciers, which results in an increased release of particles and sedimentation and, thus, a decrease in the available photosynthetic active radiation (PAR, 400-700 nm) for benthic primary production. In this study, we investigated how changes in the general sedimentation and shading patterns affect the primary production by benthic microalgae, the microphytobenthos. In order to determine potential net primary production and respiration of the microphytobenthic community, sediment cores from locations exposed to different sedimentation rates and shading were exposed to PAR of 0-70 mu.mol photons m(-2)s(-1). Total oxygen exchange rates and microphytobenthic diatom community structure, density, and biomass were determined. Our study revealed that while the microphytobenthic diatom density and composition remained similar, the net primary production of the microphytobenthos decreased with increasing sedimentation and shading. By comparing our experimental results with in situ measured PAR intensities, we furthermore identified microphytobenthic primary production as an important carbon source within Potter Cove's benthic ecosystem. We propose that the microphytobenthic contribution to the total primary production may drop drastically due to Antarctic glacial retreat and related sedimentation and shading, with yet unknown consequences for the benthic heterotrophic community, its structure, and diversity.
Highlights
The Antarctic Peninsula is one of the fastest warming areas on Earth (Ducklow et al, 2007)
The photosynthetic active radiation (PAR, 400–700 nm) can be reduced in areas influenced by glacial melt
This might affect the performance of primary producers, especially the primary production of benthic microalgae, the microphytobenthos (MPB) (Dayton et al, 1986; Skowronski et al, 2009), since they are dependent on the water depth-related light attenuation
Summary
The Antarctic Peninsula is one of the fastest warming areas on Earth (Ducklow et al, 2007). Antarctic Microphytobenthic Potential Primary Production leads to increased turbidity (Dierssen et al, 2002) and sedimentation (Schloss et al, 1999; Pasotti et al, 2015). The photosynthetic active radiation (PAR, 400–700 nm) can be reduced in areas influenced by glacial melt. This might affect the performance of primary producers, especially the primary production of benthic microalgae, the microphytobenthos (MPB) (Dayton et al, 1986; Skowronski et al, 2009), since they are dependent on the water depth-related light attenuation. The glacial melt-related particle release and related intensive shading and burial of MPB communities might put a negative feedback on this enhanced role for MPB primary production
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