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Possible effects of iron fertilization in the Southern Ocean on atmospheric CO 2 concentration
Author(s) -
Joos Fortunat,
Siegenthaler Ulrich,
Sarmiento Jorge L.
Publication year - 1991
Publication title -
global biogeochemical cycles
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.512
H-Index - 187
eISSN - 1944-9224
pISSN - 0886-6236
DOI - 10.1029/91gb00878
Subject(s) - iron fertilization , alkalinity , environmental science , flux (metallurgy) , biological pump , geotraces , nutrient , atmospheric sciences , productivity , total organic carbon , isopycnal , environmental chemistry , oceanography , chemistry , phytoplankton , geology , seawater , organic chemistry , macroeconomics , economics
Recently, it was proposed (Baum, 1990 and Martin et al, 1990a, 1990b) that the southern ocean should be fertilized with iron to stimulate biological productivity, thus enhancing the flux of organic carbon from surface to depth, thereby lowering the concentration of inorganic carbon in surface water and in turn the atmospheric CO 2 concentration. We explore the possible impact of a hypothetical iron fertilization on atmospheric CO 2 levels during the next century using a high‐latitude exchange/interior diffusion advection model. Assuming as an upper‐limit scenario that it is possible to stimulate the uptake of the abundant nutrients in the southern ocean, the maximum atmospheric CO 2 depletion is 58 ppm after 50 years and 107 ppm after 100 years. This scenario requires completely effective Fe fertilization to be carried out over 16% of the world ocean area. Sensitivity studies and comparison with other models suggest that the errors in these limits due to uncertainties in the transport parameters, which are determined by calibrating the model with radiocarbon and validated with CFC‐11 measurements, range from −29% to +17%. If iron‐stimulated biological productivity is halted during the six winter months, the additional oceanic CO 2 uptake is reduced by 18%. Possible changes in surface water alkalinity alter the result of iron fertilization by less than +9% to −28%. Burial of the iron‐induced particle flux as opposed to remineralization in the deep ocean has virtually no influence on the atmospheric response for the considered time scale of 100 years. If iron fertilization were terminated, CO 2 would escape from the ocean and soon cancel the effect of the fertilization. The factors which determine the atmospheric CO 2 reduction most strongly are the area of fertilization, the extent to which biology utilizes the abundant nutrients, and the magnitude of future CO 2 emissions. The possible effect of fertilizing the ocean with iron is small compared to the expected atmospheric CO 2 increase over the next century, unless the increase is kept small by means of stringent measures to control CO 2 emissions.