Sukul Premasis, Lamshöft Marc, Zühlke Sebastian, Spiteller Michael
Institute of Environmental Research (INFU), University of Dortmund, Otto-Hahn-Strasse 6, 44227 Dortmund, Germany.
Chemosphere. 2008 Nov;73(8):1344-50. doi: 10.1016/j.chemosphere.2008.06.066. Epub 2008 Aug 15.
Sulfadiazine is a widely used veterinary medicine that has high potential to enter the environment, especially the soil compartment by the application of manure on agricultural land and grass land or by the deposition of dung pats on pasture. Once it reaches the soil environments, it may enter into surface and ground water. Therefore, sorption-desorption behavior of sulfadiazine was studied under laboratory conditions in five different soils varying in their physicochemical properties. A batch equilibration technique was used with initial aqueous solution concentration of sulfadiazine at 5, 0.5, 0.05, and 0.005 microg mL(-1). Sorption-desorption data in soils with and without manure were well fitted with Freundlich model in log form (r(2), 0.99). A sorption-desorption hysteresis effect was apparent in all soils. A significant amount of sulfadiazine was found tightly bound to the soil particles and did not desorb after the desorption process. Moreover, presence of manure enhanced hysteresis effect. Hysteresis coefficient (H) value from soils in absence of manure (0.9-1.0) increased to the soils in presence of manure (0.9-1.8). Soils in the absence of manure showed low level of K(D Sorp.) values ranging from 0.1 to 24.3, suggesting low level sorption of sulfadiazine with appreciable risk of run-off and leaching, and in turn, surface and ground water contamination. However, presence of manure increased the sorption tendency of sulfadiazine significantly (K(D Sorp.), 6.9-40.2). K(D) values pertaining to desorption cycle increased from 1.2-90.4 to 10.4-167.3 in absence and presence of manure, respectively.
磺胺嘧啶是一种广泛使用的兽药,很有可能进入环境,尤其是通过在农田和草地上施用粪肥或在牧场上堆积粪堆进入土壤环境。一旦它进入土壤环境,就可能进入地表水和地下水。因此,在实验室条件下,研究了磺胺嘧啶在五种理化性质不同的土壤中的吸附 - 解吸行为。采用批量平衡技术,磺胺嘧啶初始水溶液浓度分别为5、0.5、0.05和0.005微克/毫升。有和没有粪肥的土壤中的吸附 - 解吸数据与对数形式的弗伦德利希模型拟合良好(r²,0.99)。在所有土壤中都明显存在吸附 - 解吸滞后效应。发现大量磺胺嘧啶紧密结合在土壤颗粒上,解吸过程后不会解吸。此外,粪肥的存在增强了滞后效应。没有粪肥的土壤的滞后系数(H)值(0.9 - 1.0)增加到有粪肥的土壤的滞后系数(0.9 - 1.8)。没有粪肥的土壤的K(D Sorp.)值较低,范围为0.1至24.3,表明磺胺嘧啶的吸附水平较低,径流和淋溶风险较高,进而导致地表水和地下水污染。然而,粪肥的存在显著增加了磺胺嘧啶的吸附趋势(K(D Sorp.),6.9 - 40.2)。与解吸循环相关的K(D)值在没有粪肥和有粪肥的情况下分别从1.2 - 90.4增加到10.4 - 167.3。
