Arsenic mobility and bioavailability in paddy soil under iron compound amendments at different growth stages of rice

Iron (Fe)-based solids can reduce arsenic (As) mobility and bioavailability in soils, which has been well recognized. However, to our knowledge, there are few studies on As uptake at different growth stages of rice under Fe compound amendments. In addition, the formation of Fe plaques at different g...

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Bibliographic Details
Published in:Environmental pollution (1987) 2017-05, Vol.224, p.136-147
Main Authors: Yu, Huan-Yun, Wang, Xiangqin, Li, Fangbai, Li, Bin, Liu, Chuanping, Wang, Qi, Lei, Jing
Format: Article
Language:English
Subjects:
Adsorption - drug effects
Arsenic - analysis
Arsenic - metabolism
Arsenic bioavailability
Arsenic fractionation
Biological Availability
China
Edible Grain - drug effects
Edible Grain - growth & development
Edible Grain - metabolism
Environmental Monitoring
Fe fractions
Fe plaques
Ferric Compounds - metabolism
Ferric Compounds - pharmacology
Humans
Oryza - drug effects
Oryza - growth & development
Oryza - metabolism
Plant Leaves - drug effects
Plant Leaves - growth & development
Plant Leaves - metabolism
Plant Roots - drug effects
Plant Roots - growth & development
Plant Roots - metabolism
Soil - chemistry
Soil amendments
Soil Pollutants - analysis
Soil Pollutants - metabolism
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Summary:Iron (Fe)-based solids can reduce arsenic (As) mobility and bioavailability in soils, which has been well recognized. However, to our knowledge, there are few studies on As uptake at different growth stages of rice under Fe compound amendments. In addition, the formation of Fe plaques at different growth stages of rice has also been rarely reported. Therefore, the present study was undertaken to investigate As mobility and bioavailability in paddy soil under Fe compound amendments throughout the whole growth stage of rice plants. Amendments of poorly crystalline Fe oxides (PC-Fe), FeCl2+NaNO3 and FeCl2 reduced grain As by 54% ± 3.0%, 52% ± 3.0% and 46% ± 17%, respectively, compared with that of the non-amended control. The filling stage was suggested to be the key stage to take measures to reduce As uptake. At this stage, all soil amendments significantly reduced As accumulation in rice plants. At the maturation stage, PC-Fe amendment significantly reduced mobile pools and increased immobile pools of soil As. Besides, PC-Fe treatment promoted the transformation of Fe fractions from dissolved Fe to adsorbed, poorly crystalline and free Fe oxides. Moreover, significant positive correlations between soil Fe fractions and As fractions were found. Accordingly, we hypothesized that Fe compound amendments might affect the concentration distribution of Fe fractions first and then affect As fractionation in soil and its bioavailability to rice plants indirectly. The formation of Fe plaques varied with growth stages and different treatments. Significantly negative correlations between mobile pools of As and Fe or As in Fe plaques indicated that Fe plaques could immobilize mobile As in soils and thus affect As bioavailability. Overall, the effect of the soil amendments on reduction of As uptake varied with growth stages and different treatments, and further research on the key stage for reducing As uptake is still required. [Display omitted] •PC-Fe was the most effective amendment to reduce As accumulation in rice plants.•The filling stage was the key stage to take measures to reduce As uptake.•The formation of Fe plaques varied with the growth stages and different treatments.•Mobile As in soils was significantly correlated with Fe or As in Fe plaques. Arsenic mobility and bioavailability in paddy soil at the whole growth stage under different Fe compound amendments were investigated.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2017.01.072