Tile-drainage in the Corn Belt has a great impact on surface water quality, at all scales (field, watershed and drainage basin) especially by increasing nitrate loads in the Mississippi River. An improved understanding of flow and transport is essential to better manage these ecosystems. However, such systems are extremely difficult to characterize and model since the regulating processes are dominated by preferential flow mechanisms that exhibit great spatial and temporal variations. The objectives of the present effort are to (1) Develop experimental data set describing flow and transport in tile-drained fields suitable for model development and evaluation, (2) Evaluate observed spatial and temporal variations in flow and transport processes to identify empirical relationships between variables, (3) Characterize solute travel time distributions relative to chemical application distance from tile drains, and (4) Provide an improved understanding of relationships between tile effluent response and climatic and soil variables. To achieve these objectives, environmental monitoring (e.g., rainfall, soil moisture, evaporation, flow, effluent sampling) over an extended period was performed within four replicate (27.4 x 30.5 m) tile drained field plots designed to provide hydraulic isolation. On two of the plots four chemicals were surface applied, one to each of four 1-m wide bands which ran parallel to the drains. The spatial distributions of chemicals within the soil were characterized by coring five days and one year after application, and tile effluent samples were collected and analyzed to provide effluent time-series. Chapter 4 provides a detailed analysis of tile flow response under the influences of variable climatic and hydrologic conditions, and identifies factors that regulate preferential flows. Chapter 5 describes the water balance model development and provides an analysis for each of 15 drainage cycles, with a clear demarcation identified between summer and winter cycle responses. A precise water balance was calculated which included development of a new method for modeling bare soil evaporation during repeated wetting and drying cycles. This method performed well in comparison with the HYDRUS numerical model. Chapter 6 evaluates the chemical transport processes with a special focus on preferential flow and transport, providing insight into associated governing factors. Finally, the last chapter provides conclusions and suggestions for future research.
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机译:玉米带中的瓷砖排水对所有规模(田野,集水区和排水盆地)的地表水质量都有很大影响,特别是通过增加密西西比河中的硝酸盐负荷。更好地了解流量和运输对于更好地管理这些生态系统至关重要。然而,由于调节过程由表现出巨大的时空变化的优先流动机制所控制,所以这种系统极难表征和建模。当前工作的目标是(1)开发描述适合模型开发和评估的排水区域中流动和输运的实验数据集,(2)评估流动和输运过程中观察到的时空变化,以识别之间的经验关系。变量,(3)表征相对于距瓷砖排水沟的化学应用距离的溶质传播时间分布,以及(4)更好地理解瓷砖废水响应与气候和土壤变量之间的关系。为了实现这些目标,在旨在提供水力隔离的四个重复(27.4 x 30.5 m)瓷砖排水田地中进行了长时间的环境监测(例如降雨,土壤湿度,蒸发,流量,污水取样)。在其中两个地块上,对四种化学物质进行了表面施涂,每四个平行于排水管的1-m宽带各一个。在施用后五天和一年取芯,以表征土壤中化学物质的空间分布,并收集和分析瓷砖出水样品以提供出水时间序列。第4章详细分析了在可变气候和水文条件影响下的瓷砖流动响应,并确定了调节优先流动的因素。第5章介绍了水平衡模型的发展,并针对15个排水循环中的每个循环进行了分析,并在夏季和冬季循环响应之间确定了明确的界限。计算出了精确的水平衡,其中包括开发了一种新的方法,该方法可用于模拟在重复的润湿和干燥周期中裸露的土壤蒸发。与HYDRUS数值模型相比,该方法表现良好。第6章评估化学品的运输过程,重点关注优先流动和运输,从而深入了解相关的控制因素。最后,最后一章为今后的研究提供了结论和建议。
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