Rainwater-borne H2O2 accelerates roxarsone degradation and reduces bioavailability of arsenic in paddy rice soils.

Journal of hazardous materials Pub Date : 2024-10-05 Epub Date: 2024-08-23 DOI:10.1016/j.jhazmat.2024.135633
Kaiqing Fan, Liji Chen, Huashou Li, Jun Wei Lim, Chuxia Lin, Junhao Qin, Rongliang Qiu
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Abstract

Contamination of rice by arsenic represents a significant human health risk. Roxarsone -bearing poultry manure is a major pollution source of arsenic to paddy soils. A mesocosm experiment plus a laboratory experiment was conducted to reveal the role of rainwater-borne H2O2 in the degradation of roxarsone in paddy rice soils. While roxarsone could be degraded via chemical oxidation by Fenton reaction-derived hydroxyl radical, microbially mediated decomposition was the major mechanism. The input of H2O2 into the paddy soils created a higher redox potential, which favored certain roxarsone-degrading and As(III)-oxidizing bacterial strains and disfavored certain As(V)-reducing bacterial strains. This was likely to be responsible for the enhanced roxarsone degradation and transformation of As(III) to As(V). Fenton-like reaction also tended to enhance the formation of Fe plaque on the root surface, which acted as a filter to retain As. The dominance of As(V) in porewater, combined with the filtering effect of Fe plaque significantly reduced the uptake of inorganic As by the rice plants and consequently its accumulation in the rice grains. The findings have implications for developing management strategies to minimize the negative impacts from the application of roxarsone-containing manure for fertilization of paddy rice soils.

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雨水中的 H2O2 可加速洛克沙砷的降解,降低砷在水稻田土壤中的生物利用率。
砷污染水稻对人类健康构成重大威胁。含洛克沙砷的家禽粪便是稻田土壤中砷的主要污染源。为了揭示雨水携带的 H2O2 在稻田土壤中洛克沙砷降解过程中的作用,我们进行了中观宇宙实验和实验室实验。虽然洛克沙砷可以通过芬顿反应产生的羟基自由基进行化学氧化降解,但微生物介导的分解是主要机制。向稻田土壤中输入 H2O2 会产生较高的氧化还原电位,有利于某些洛克沙砷降解菌株和氧化 As(III)菌株,不利于某些还原 As(V)菌株。这很可能是罗沙松降解和 As(III) 转化为 As(V) 增强的原因。芬顿样反应还倾向于促进根表面铁斑块的形成,而铁斑块则起着过滤作用,可以截留 As。As(V) 在孔隙水中占主导地位,再加上铁斑的过滤作用,大大减少了水稻植株对无机砷的吸收,从而减少了无机砷在稻粒中的积累。这些发现有助于制定管理策略,最大限度地减少施用含洛克沙砷的粪肥对水稻田土壤的负面影响。
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