Facultad de Ingeniería, Universidad Autónoma de Yucatán, Av. Industrias no Contaminantes por Periférico Norte, Apdo. Postal 150, Cordemex, CP 97310 Mérida, Yucatán, Mexico.
Facultad de Ingeniería, Universidad Autónoma de Yucatán, Av. Industrias no Contaminantes por Periférico Norte, Apdo. Postal 150, Cordemex, CP 97310 Mérida, Yucatán, Mexico.
Sci Total Environ. 2021 Jun 10;772:145038. doi: 10.1016/j.scitotenv.2021.145038. Epub 2021 Feb 2.
Agriculture effluents from cleaning and handling equipment used in pesticide applications can contaminate superficial and groundwater sources when not correctly disposed of. Biobeds using soil enriched with amendments represent a viable technology to control and minimize pesticide pollution of soil and water in farmlands. They are usually installed outdoors without protection, making them vulnerable to rain flooding, lack of moisture, drought, and intense heat or cold. Temperature (T) and moisture (M) of the biomixture are considered two of the most important physical factor affecting pesticide dissipation. This study aimed to evaluate the effect of T and M on the dissipation of five of the most used pesticides (carbofuran, atrazine, 2,4-D, diazinon, and glyphosate) in Yucatan State, Mexico. Three experiments using miniaturized biobeds considering optimal temperature and moisture (T of 30 ± 2 °C and 90% water holding capacity [WHC]) were performed. The optimal dissipation time and the effect of T, M variations, and volatilization was determined. The optimal dissipation time was over 14 days. Carbofuran was the least dissipated pesticide and glyphosate the most. The primary factor affecting pesticide dissipation was T (P < 0.05), reaching rates of dissipation of 99% at 45 °C. Variations of M in the biomixture were not significant on pesticide dissipation (P > 0.05). The white-rot fungi were observed; its presence was related to increments of T. Head Space analysis (at 45 °C) showed low pesticide volatilization (≤0.03%) for all pesticide used were quantified; water vapor condensation could reduce the pesticide volatilization for experimental conditions.
农业废水来自清洁和处理设备在农药应用可以污染地表水和地下水的来源时不正确处理。生物床使用土壤丰富的改良剂代表了一种可行的技术来控制和最大限度地减少农药污染的土壤和水在农田。它们通常安装在户外没有保护,使他们容易受到雨水洪水,缺乏水分,干旱,和强烈的热或冷。温度(T)和水分(M)的混合物被认为是两个最重要的物理因素影响农药的消散。本研究旨在评估 T 和 M 对消解的五个最常用的农药(克百威、莠去津、2,4 - D、二嗪磷和草甘膦)在尤卡坦州,墨西哥。三个实验使用微型生物床考虑最佳温度和水分(T 的 30 ± 2 ° C 和 90%水持水量[WHC])。最优消解时间和 T 的影响,水分变化,挥发。最佳消解时间超过 14 天。克百威是最不容易消散的农药和草甘膦的最。主要影响农药消解是 T (P < 0.05),达到 99%的消解率在 45 ° C。变化的 M 在生物混合物中对农药消解不显著(P > 0.05)。白腐真菌被观察到;它的存在与 T 的增量有关。顶空气体分析(在 45 ° C)表明低农药挥发(≤ 0.03%)为所有农药都被量化;水汽凝结可以减少农药挥发的实验条件。