Your search keyword '"hydromorphic soils"' showing total 4 results

1. Mercury mobilization by chemical and microbial iron oxide reduction in soils of French Guyana.

Author

Harris-Hellal, Jennifer, Grimaldi, Michel, Garnier-Zarli, Evelyne, and Bousserrhine, Noureddine

Subjects

*IRON oxides, *MERCURY in soils, *IRON, *SOIL composition, *SOIL microbiology, *GEOCHEMISTRY, *HYDROMORPHIC soils

Abstract

Iron oxy(hydr)oxides (oxides) are important mercury sinks in tropical oxisols and the geochemistry of these two elements are thus closely entwined. We hypothesized that bacterial Fe-oxide reduction in anoxic conditions could be a significant mechanism for mobilizing associated Hg. Iron oxide and mercury solubilisation in presence of two chemical reducers (ascorbate and dithionite, dissolving amorphous and amorphous plus well crystallized Fe-oxides, respectively) was compared to their solubilisation in presence of autochthonous ferri-reducing bacteria. This work was carried out on two soil profiles from a small catchment basin in French Guyana, an oxisol (O) from a well drained slope and a water-saturated hydromorphic soil (H). The chemical reductions showed that in the oxisol 20 and 48% of total Hg (Hg) was associated to amorphous and well crystallized iron oxides, respectively. However, in the hydromorphic soil, no Hg seemed to be associated to amorphous iron oxides while the well crystallized fraction contained less than 9% of Hg. Chemical Fe-oxide reduction showed that Hg solubility was correlated to Fe reduction in the oxisol, demonstrating a relationship between the geochemistry of these two metals. During bacterial growth, while bacterial iron reduction solubilised up to 3.2 mg Fe g soil in the oxisol sample, Hg remained unchanged. No mercury was detected in the culture medium either. However, chemical analysis showed a decrease of the amounts of Hg associated to amorphous and well crystallized Fe-oxides after 14 days of incubation, underlining the potential for iron-reducing bacteria to modify mercury distribution in soil. [ABSTRACT FROM AUTHOR]

Published

2011

2. Water table elevation controls on soil nitrogen cycling in riparian wetlands along a European climatic gradient.

Author

Hefting, M., Clément, J. C., Dowrick, D., Cosandey, A.C., Bernal, S., Cimpian, C., Tatur, A., Burt, T.P., and Pinay, G.

Subjects

*AMMONIA, *DENITRIFICATION, *NITROGEN in soils, *NITROGEN removal (Water purification), *HYDROMORPHIC soils, *RIPARIAN areas

Abstract

Riparian zones have long been considered as nitrate sinks in landscapes. Yet, riparian zones are also known to be very productive ecosystems with a high rate of nitrogen cycling. A key factor regulating processes in the N cycle in these zones is groundwater table fluctuation, which controls aerobic/anaerobic conditions in the soil. Nitrification and denitrification, key processes regulating plant productivity and nitrogen buffering capacities are strictly aerobic and anaerobic processes, respectively. In this study we compared the effects of these factors on the nitrogen cycling in riparian zones under different climatic conditions and N loading at the European scale. No significant differences in nitrification and denitrification rates were found either between climatic regions or between vegetation types. On the other hand, water table elevation turned out to be the prime determinant of the N dynamics and its end product. Three consistent water table thresholds were identified. In sites where the water table level is within -10 cm of the soil surface, ammonification is the main process and ammonium accumulates in the topsoils. Average water tables between -10 and -30 cm favour denitrification and therefore reduce the nitrogen availability in soils. In drier sites, that is, water table level below -30 cm, nitrate accumulates as a result of high net nitrification. At these latter sites, denitrification only occurs in fine textured soils probably triggered by rainfall events. Such a threshold could be used to provide a proxy to translate the consequences of stream flow regime change to nitrogen cycling in riparian zones and consequently, to potential changes in nitrogen mitigation. [ABSTRACT FROM AUTHOR]

Published

2004

3. Do Deep Tree Roots Provide Nutrients to the Tropical Rainforest?

Author

Poszwa, Anne, Dambrine, Etienne, Ferry, Bruno, Pollier, Benoît, and Loubet, Michel

Published

2002

4. Evolution of lipid abundance and molecular composition during the podzolisation of laterites in the upper Amazon basin

Author

Bardy, Marion, Derenne, Sylvie, and Fritsch, Emmanuel

Published

2009