Citation:

Dai, T., R B. Ambrose Jr., K. Alvi, T A. Wool, H. Manguerra, M. Chokshi, H. Yang, AND S R. Kraemer. CHARACTERIZING SPATIAL AND TEMPORAL DYNAMICS: DEVELOPMENT OF A GRID-BASED WATERSHED MERCURY LOADING MODEL. Presented at 2005 Watershed Management Conference, Williamsburg, VA, July 20-23, 2005.

Impact/Purpose:

To improve the scientific understanding of the linkage between fish methylmercury and ambient mercury in the environment.

To complete a model for transformation and bioaccumulation of mercury than can be linked with models for atmospheric deposition and hydrology to yield a multimedia integrated modeling system capable of quantifying regional exposure to mercury.

To apply state of the art watershed and water body modeling to assess exposures to mercury for impacted aquatic ecosystems.

Description:

A distributed grid-based watershed mercury loading model has been developed to characterize spatial and temporal dynamics of mercury from both point and non-point sources. The model simulates flow, sediment transport, and mercury dynamics on a daily time step across a diverse landscape. The model is composed of six major components: (1) an ArcGIS interface for processing spatial input data; (2) a basic hydrological module; (3) a sediment transport module; (4) a mercury transport and transformation module; (5) a spreadsheet-based model post-processor; and (6) links to other models such as WASP and WhAEM 2000 developed by the U.S. Environmental Protection Agency (U.S. EPA). The model fully uses the grid processing capacity of the latest ArcGIS technology. The water balance, sediment generation and transport, and mercury dynamics are calculated for every grid within a watershed. Water and pollutants are routed daily throughout the watershed based on a unique and flexible algorithm that characterizes a watershed into many runoff travel-time zones. The mercury transport and transformation module simulates the following key processes: (1) mercury input from atmospheric deposition; (2) mercury assimilation and accumulation in forest canopy and release from forest fitter; (3) mercury input from bedrock weathering; (4) mercury transformation in soils; (5) mercury transformation in lakes and wetlands including reduction and net methylation; (6) mercury transport through sediment and runoff, and (7) mercury transport in stream channels. By using the grid-based technology, flow and mercury dynamics can be examined at any of several points in the watershed. The model is capable of supporting large-scale watershed modeling with high-resolution raster datasets and will be used in mercury research projects sponsored by U.S. EPA. The model is programmed in Visual Basic and requires two ArcGIS (version 9.0) components- ArcVIew 9 and the Spatial Analyst extension.

Record Details: