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Journal Articles Soil Science Society of America Journal Year : 2009

Impact of Redox Cycles on Manganese, Iron, Cobalt, and Lead in Nodules

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Abstract

Redox processes are responsible for Fe and Mn segregation as Fe–Mn oxide coatings or nodules. These nodules are also trace element scavengers in soils. Redox processes are of particular importance in seasonally saturated soil containing naturally high concentrations of trace metals. We investigated the dynamics of Fe–Mn nodules and two associated trace elements, Co and Pb, under controlled redox conditions in a column experiment, including five columns fed with mimicked topsoil solution that was elevated in Fe and Mn. The results show that the redox conditions reached 100 mV, which was sufficient to dissolve Mn oxides and release the associated Co, while Pb was readsorbed onto nodule surfaces. The amounts of Mn and Co released into the water were small compared with the quantities stored in the nodules (<0.1% of the initial stock stored in the nodules). The redox conditions were insufficient, however, to allow Fe oxide dissolution. On the contrary, 70 to 90% of the Fe entering the column was fixed onto the nodules. In terms of an environmental threat, these results showed that Pb would not be released from soil during nodule dissolution, whereas Co, which is less toxic, would be released.
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Dates and versions

insu-00433531 , version 1 (31-07-2011)

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Sophie Cornu, J.A. Cattle, Anatja Samouëlian, C. Laveuf, Patrick Albéric. Impact of Redox Cycles on Manganese, Iron, Cobalt, and Lead in Nodules. Soil Science Society of America Journal, 2009, 73 (4), pp.1231-1241. ⟨10.2136/sssaj2008.0024⟩. ⟨insu-00433531⟩
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