Photobiological effects on ice algae of a rapid whole-fjord loss of snow cover during spring growth in Kangerlussuaq, a West Greenland Fjord
Sorrell, Brian K; Hawes, Ian; Stratmann, T.; Lund-Hansen, Lars Chresten
(2021) Journal of Marine Science and Engineering, volume 9, issue 8, pp. 1 - 14
(Article)
Abstract
Snow cover on sea ice is the most important factor controlling light availability for sea ice algae, but it is predicted by climate models to become more variable and stochastic. Here, we document effects of a sudden, complete loss of the entire snow cover on first-year sea ice at Kangerlussuaq
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Fjord, West Greenland, due to a natural Föhn wind event that caused a ca. 17◦ C air temperature increase over 36 h. We applied Imaging-PAM fluorometry to examine effects of snow cover on algal distribution and photobiology and observed a rapid decrease in algal biomass associated with loss of the skeletal ice crystal layer on the underside of the ice that had supported most of the visible algae. Furthermore, the remaining algae were photobiologically stressed, as seen in a significant decrease in the dark-acclimated fluorescence yield (ΦPSII_max) from 0.55 before snow loss to 0.41 after. However, recovery in the dark suggested that non-photosynthetic quenching was successfully dissipating excess energy in the community and that there was little photodamage. An observed decrease in the photosynthetic efficiency α from 0.22 to 0.16 µmol é m−2 s−1 is therefore likely to be due to photoacclimation and the change in community composition. Centric diatoms and flagellates were the main taxa lost in the snow loss event, whereas the sea ice specialist Nitzschia frigida increased in numbers. These observations are similar to those seen in artificial snow-clearing experiments and consistent with snow clearing being a useful approach for investigating the complex interactions between snow cover, irradiance fluctuations, and ice algal performance.
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Keywords: Greenland, Ice algae, Optics, Photobiology, Snow cover, Stress, Civil and Structural Engineering, Water Science and Technology, Ocean Engineering
ISSN: 2077-1312
Publisher: Multidisciplinary Digital Publishing Institute
Note: Funding Information: Funding: This project was funded by the Danish Council for Independent Research (Project DFF– 1323-00335: Sea ice ecosystems: Ecological effects of a thinning snow cover), the New Zealand Ministry of Business, Innovation and Employment (Project ANTA1801), the Carlsberg Foundation, Aarhus University, and the Hartmann Brothers Foundation and was developed in the frame of the project FACE-IT (The Future of Arctic Coastal Ecosystems—Identifying Transitions in Fjord Systems and Adjacent Coastal Areas). FACE-IT has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No. 869154. Funding Information: This project was funded by the Danish Council for Independent Research (Project DFF? 1323-00335: Sea ice ecosystems: Ecological effects of a thinning snow cover), the New Zealand Ministry of Business, Innovation and Employment (Project ANTA1801), the Carlsberg Foundation, Aarhus University, and the Hartmann Brothers Foundation and was developed in the frame of the project FACE-IT (The Future of Arctic Coastal Ecosystems?Identifying Transitions in Fjord Systems and Adjacent Coastal Areas). FACE-IT has received funding from the European Union?s Horizon 2020 research and innovation program under grant agreement No. 869154. We thank the staff at Kangerlussuaq International Science Support (KISS) for logistical help and assistance. We thank Per Andersen for species identifications and Ida Marie Deichmann for laboratory assistance. Publisher Copyright: © 2021 by the authors. Licensee MDPI, Basel, Switzerland.
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