The Growth Response of Two Diatom Species to Atmospheric Dust from the Last Glacial Maximum
Relief of iron (Fe) limitation in the surface Southern Ocean has been suggested as one driver of the regular glacial-interglacial cycles in atmospheric carbon dioxide (CO$_2$). The proposed cause is enhanced deposition of Fe-bearing atmospheric dust to the oceans during glacial intervals, with conse...
Main Authors: | , , , , |
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Format: | Article in Journal/Newspaper |
Language: | English |
Published: |
Public Library of Science
2016
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Subjects: | |
Online Access: | https://www.repository.cam.ac.uk/handle/1810/260659 https://doi.org/10.17863/CAM.4892 |
Summary: | Relief of iron (Fe) limitation in the surface Southern Ocean has been suggested as one driver of the regular glacial-interglacial cycles in atmospheric carbon dioxide (CO$_2$). The proposed cause is enhanced deposition of Fe-bearing atmospheric dust to the oceans during glacial intervals, with consequent effects on export production and the carbon cycle. However, understanding the role of enhanced atmospheric Fe supply in biogeochemical cycles is limited by knowledge of the fluxes and 'bioavailability' of atmospheric Fe during glacial intervals. Here, we assess the effect of Fe fertilization by dust, dry-extracted from the Last Glacial Maximum portion of the EPICA Dome C Antarctic ice core, on the Antarctic diatom species $\textit{Eucampia antarctica}$ and $\textit{Proboscia inermis}$. Both species showed strong but differing reactions to dust addition. $\textit{E. antarctica}$ increased cell number (3880 vs.786 cells mL$^{-1}$), chlorophyll a (51 vs. 3.9 μg mL$^{-1}$) and particulate organic carbon (POC; 1.68 vs. 0.28 μg mL$^{-1}$) production in response to dust compared to controls. $\textit{P. inermis}$ did not increase cell number in response to dust, but chlorophyll $a$ and POC per cell both strongly increased compared to controls (39 vs. 15 and 2.13 vs. 0.95 ng cell$^{-1}$ respectively). The net result of both responses was a greater production of POC and chlorophyll $a$, as well as decreased Si:C and Si:N incorporation ratios within cells. However, $\textit{E, antarctica}$ decreased silicate uptake for the same nitrate and carbon uptake, while $\textit{P. inermis}$ increased carbon and nitrate uptake for the same silicate uptake. This suggests that nutrient utilization changes in response to Fe addition could be driven by different underlying mechanisms between different diatom species. Enhanced supply of atmospheric dust to the surface ocean during glacial intervals could therefore have driven nutrient-utilization changes which could permit greater carbon fixation for lower silica utilization. ... |
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