了解农业系统中的砷动态,以预测和防止作物吸收。
Understanding arsenic dynamics in agronomic systems to predict and prevent uptake by crop plants.
机构信息
Dartmouth College, Department of Biology, 78 College Street, Hanover, NH 03755, USA.
Dartmouth College, Department of Earth Sciences, Hanover, NH 03755, USA.
出版信息
Sci Total Environ. 2017 Mar 1;581-582:209-220. doi: 10.1016/j.scitotenv.2016.12.111. Epub 2016 Dec 30.
Abstract
This review is on arsenic in agronomic systems, and covers processes that influence the entry of arsenic into the human food supply. The scope is from sources of arsenic (natural and anthropogenic) in soils, biogeochemical and rhizosphere processes that control arsenic speciation and availability, through to mechanisms of uptake by crop plants and potential mitigation strategies. This review makes a case for taking steps to prevent or limit crop uptake of arsenic, wherever possible, and to work toward a long-term solution to the presence of arsenic in agronomic systems. The past two decades have seen important advances in our understanding of how biogeochemical and physiological processes influence human exposure to soil arsenic, and this must now prompt an informed reconsideration and unification of regulations to protect the quality of agricultural and residential soils.
摘要
这篇综述是关于农业系统中的砷,涵盖了影响砷进入人类食物链的过程。范围从土壤中的砷源(自然和人为)、控制砷形态和有效性的生物地球化学和根际过程,到作物吸收砷的机制和潜在的缓解策略。本综述提出了采取措施防止或限制作物吸收砷的建议,只要有可能,就应努力长期解决农业系统中砷的存在问题。在过去的二十年中,我们对生物地球化学和生理过程如何影响人类接触土壤砷的认识有了重要的进展,现在必须对保护农业和居住土壤质量的法规进行明智的重新考虑和统一。
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