排序方式: 共有5条查询结果,搜索用时 171 毫秒
1
1.
对取自于云南省昭通市头寨滑坡滑源区附近的两个大尺度(25cm×25cm×50cm)土柱样品进行CT扫描,选取典型剖面切片,通过CT值范围将大孔隙分离从而研究土体中的大孔隙分布;计算大孔隙分布分维数(盒维数),研究其大孔隙的不规则特征,结果表明:土体中大孔隙的盒维数随深度增加呈单调递减规律,且与大孔隙度具有显著正相关关系;但大孔隙度只能表征在某一深度上大孔隙的分布多少,而大孔隙的不规则特征则需盒维数表征;最后得到大孔隙的累积大孔隙度与大孔隙孔径(在盒维数为常数时)符合幂函数规律,研究结果有利于利用分形理论建立大孔隙模型,从而研究水分在大孔隙中运动过程。 相似文献
2.
呋喃丹和阿特拉津在土柱中的淋溶及其影响因素 总被引:5,自引:0,他引:5
通过室内柱淋溶试验研究呋喃丹与阿特拉津在河南潮土及2种太湖水稻土中的淋溶作用及其影响因素。结果表明:2种农药在河南潮土中的淋溶作用比在太湖水稻土中弱。在表土中添加2 mg农药、模拟1次降水200mm条件下,呋喃丹最大淋溶量峰值可达25—30 cm深处,阿特拉津最大淋溶量峰值可达15—20 cm。表明呋喃丹、阿特拉津2种农药在供试土柱中均表现出较强淋溶特性。土壤和农药性质对淋溶作用均有很大影响。土壤有机质和粘粒含量越高,对农药的吸附性越强,土壤中农药越不容易随水下移;土壤大孔隙越多,农药在土壤中淋溶作用也越强,且相邻大孔隙对农药淋溶存在协同作用。土柱中插入4根直形多孔玻璃管后,土壤淋出液中农药量比插入2根的高2.7倍,比不插玻璃管对照高10倍。土柱中插入扭曲(60°)形玻璃管与插入直形玻璃管相比,农药在土壤中持留性增强,淋溶作用减弱。同一土柱中农药水溶性越大,淋溶作用也越强。 相似文献
3.
Loss of Pesticides from Agricultural Fields in SE Norway – Runoff Through Surface and Drainage Water
G. Riise H. Lundekvam Q.L. Wu L.E. Haugen J. Mulder 《Environmental geochemistry and health》2004,26(2):269-276
Loss of two pesticides with different mobility characteristics, bentazone (Koc 34) and propiconazole (Koc 1800), were studied at three agricultural fields (Askim, Bjørnebekk and Syverud) in SE Norway. A conservative tracer (Br) was used to follow the flow of water. The loss of pesticides varied among the fields, depending on hydrological characteristics and soil properties. The loss of pesticides was higher from two artificially levelled silty clay loam soils with poor aggregate stability (Askim and Bjørnebekk) compared to a loam/silt loam soil with increased content of organic carbon and better aggregate stability (Syverud). The total accumulated loss was <0.5% from all fields. The highest pesticide concentrations were measured at the first runoff episode after application for both the mobile (bentazone) and less mobile pesticide (propiconazole) in the surface runoff. In the drainage water, the peak for the less mobile pesticide coincided with the Br tracer, while the peak for mobile pesticide appeared earlier than the Br tracer. Rapid movement of water, particles and pesticides through soils indicate flow through macropores. Larger proportions (in percent of total applied) of both the mobile and the strongly sorbed pesticides were lost through the drainage as compared to the loss through surface runoff at Askim. Here, it is suggested that macropore flow contribute to the increased loss of pesticides through the drainage. At Syverud, high infiltration capacity reduces the amount of water available for surface runoff, and somewhat higher loss of the mobile pesticide was registered in the drainage compared to the surface runoff. For the strongly sorbed pesticide, however, propiconazole was neither detected in surface nor in drainage water at Syverud. Generally, there was a higher percentage loss of the mobile compared to the strongly sorbed pesticide in both surface and drainage water, which is in agreement with the pesticides mobility characteristics in soil. An exception was, however, the erodible soil Bjørnebekk, where a higher fraction of propiconazole was lost in the surface runoff compared to bentazone. Large amounts of sediment transport from the Bjørnebekk field probably contributed to enhanced transport of the strongly sorbed pesticide. 相似文献
4.
大孔隙对纳米CeO2在多孔介质中迁移行为的影响 总被引:1,自引:0,他引:1
研究了不同类型大孔隙对纳米CeO_2在石英砂柱中迁移的影响,并运用两区物理化学非平衡模型对纳米CeO_2流出曲线进行拟合和参数估算.结果表明,含横孔(垂直水流运动方向)石英砂柱中纳米CeO_2的流出曲线与均匀石英砂柱十分接近,横孔对于纳米CeO_2在石英砂介质中的迁移影响较弱.与均匀石英砂柱相比,含竖孔(平行水流运动方向)石英砂柱中纳米CeO_2流出曲线明显不同于均匀石英砂柱,其初始穿透时间明显提前,初始穿透浓度和初始回收率显著增加,竖孔对于纳米CeO_2在石英砂介质中的迁移起促进作用,特别是贯通竖孔.两区物理化学非平衡模型可以很好地拟合纳米CeO_2在含有大孔隙石英砂柱中的迁移.通过分析模型参数质量交换系数(ωph、αch)和分配系数(Kd)得出,含横孔石英砂柱中纳米CeO_2在两区间的质量交换能力和吸附作用较强,而含有竖孔石英砂柱中纳米CeO_2在两区间的质量交换能力和吸附作用较弱. 相似文献
5.
1