Phosphorus and Glyphosate Adsorption and Desorption Trends across Different Depths in Sandy Soil

Rachel A. Fenn, Davie M. Kadyampakeni, Ramdas G. Kanissery, Jonathan Judy, Mahesh Bashyal
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引用次数: 1

Abstract

The unintended loss of glyphosate and P from cropland may pose an environmental risk to downstream water quality and marine ecosystems. Glyphosate and P compete for exchange sites, and since glyphosate is an organophosphate, it reacts similarly to phosphates in soil. The competition for exchange sites between glyphosate and P could lead to an increased risk of loss due to leaching, leading to water quality degradation and harm to aquatic wildlife. The focus of this study was to (i) determine the sorption tendencies of P and orthophosphate in Florida Entisols and (ii) determine the sorption tendencies of glyphosate in Florida Entisols. Adsorption and desorption experiments were performed for both P and glyphosate. The data from the sorption experiments were fitted to linear, Freundlich, and Langmuir models. Orthophosphate-P (ortho-P) was best represented by the linear isotherm. Glyphosate adsorption was best represented by the linear isotherm, and desorption was best represented by both the linear and Freundlich models. Phosphorus and glyphosate sorption and desorption increased with soil depth, likely due to the higher concentrations of Fe and Al with greater depth. These results could improve P and glyphosate application rates when applied in tandem to citrus trees, increasing overall tree health and improving soil quality.
不同深度沙质土壤中磷和草甘膦的吸附和解吸趋势
农田中草甘膦和磷的意外损失可能对下游水质和海洋生态系统构成环境风险。草甘膦和磷争夺交换位点,由于草甘膦是一种有机磷,它与土壤中的磷酸盐反应相似。草甘膦和磷之间对交换地点的竞争可能导致浸出损失的风险增加,导致水质退化和对水生野生动物的危害。本研究的重点是(i)确定P和正磷酸盐在佛罗里达Entisols中的吸附趋势和(ii)确定草甘膦在佛罗里达Entisols中的吸附趋势。对磷和草甘膦进行了吸附和解吸实验。吸附实验的数据拟合为线性、Freundlich和Langmuir模型。正磷酸盐- p (orthp - p)用线性等温线表示最好。线性等温线最能代表草甘膦的吸附,线性和Freundlich模型最能代表草甘膦的脱附。磷和草甘膦的吸附和解吸随土壤深度的增加而增加,可能是由于铁和铝的浓度随土壤深度的增加而增加。这些结果可以提高P和草甘膦在柑橘树上的施用量,提高树木整体健康,改善土壤质量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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