Aluminum effects on marine phytoplankton: implications for a revised Iron Hypothesis (Iron-Aluminum Hypothesis)

In contrast to substantial studies and established knowledge of aluminum (Al) effects (mainly toxicity) on freshwater organisms and terrestrial plants, and even on human health, only a few studies of Al effects on marine organisms have been reported, and our understanding of the role of Al in marine...

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Bibliographic Details
Published in:Biogeochemistry
Main Authors: Zhou, Linbin, Tan, Yehui, Huang, Liangmin, Fortin, Claude, Campbell, Peter G. C.
Format: Report
Language:English
Published: SPRINGER 2018
Subjects:
Environmental Sciences & Ecology
Geology
Aluminum
Marine phytoplankton
Iron Hypothesis
Fe-Al Hypothesis
Beneficial effects
Biological pump
Environmental Sciences
Geosciences
Multidisciplinary
NORTH-ATLANTIC OCEAN
SOUTH CHINA SEA
DISSOLVED ALUMINUM
BIOGENIC SILICA
PROOXIDANT ACTIVITY
PACIFIC-OCEAN
ICE CORE
THALASSIOSIRA-WEISSFLOGII
EXTRACELLULAR-SUPEROXIDE
BIOLOGICAL-SYSTEMS
Pacific
ice core
North Atlantic
Online Access:http://ir.gig.ac.cn/handle/344008/39132
https://doi.org/10.1007/s10533-018-0458-6
Description
Summary:In contrast to substantial studies and established knowledge of aluminum (Al) effects (mainly toxicity) on freshwater organisms and terrestrial plants, and even on human health, only a few studies of Al effects on marine organisms have been reported, and our understanding of the role of Al in marine biogeochemistry is limited. In this paper, we review the results of both field and laboratory experiments on the effects of Al on marine organisms, including Al toxicity to marine phytoplankton and the beneficial effects of Al on marine phytoplankton growth, and we discuss possible links of Al to the biological pump and the global carbon cycle. We propose a revised Iron (Fe) Hypothesis, i.e., the Fe-Al Hypothesis that introduces the idea that Al as well as Fe play an important role in the glacial-interglacial change in atmospheric CO2 concentrations and climate change. We propose that Al could not only facilitate Fe utilization, dissolved organic phosphorus utilization and nitrogen fixation by marine phytoplankton, enhancing phytoplankton biomass and carbon fixation in the upper oceans, but also reduce the decomposition and decay of biogenic matter. As a result, Al allows potentially more carbon to be exported and sequestered in the ocean depths through the biological pump. We also propose that Al binds to superoxide to form an Al-superoxide complex, which could catalyze the reduction of Fe(III) to Fe(II) and thus facilitate Fe utilization by marine phytoplankton and other microbes. Further ocean fertilization experiments with Fe and Al are suggested, to clarify the role of Al in the stimulation of phytoplankton growth and carbon sequestration in the ocean depths.

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