@article{22015, keywords = {Alpha-HCH, Fugacity, Global, Long-range transport, Model}, author = {Liisa Toose and David G Woodfine and Matthew Macleod and Donald Mackay and Jennifer Gouin}, title = {BETR-World: a geographically explicit model of chemical fate: application to transport of α-HCH to the Arctic}, abstract = {

The Berkeley–Trent (BETR)-World model, a 25 compartment, geographically explicit fugacity-based model is described and applied to evaluate the transport of chemicals from temperate source regions to receptor regions (such as the Arctic). The modelwas parameterized using GIS and an array of digital data on weather, oceans, freshwater, vegetation and geo-political boundaries. This version of the BETR model framework includes modi.cation of atmospheric degradation rates by seasonally variablehydroxyl radical concentrations and temperature. Degradation rates in all other compartments vary with seasonally changing temperature. Deposition to the deep ocean has been included as a loss mechanism. A case study was undertaken for a-HCH.Dynamic emission scenarios were estimated for each of the 25 regions. Predicted environmental concentrations showed good agreement with measured values for the northern regions in air, and fresh and oceanic water and with the results from a previousmodel of global chemical fate. Potential for long-range transport and deposition to the Arctic region was assessed using a Transfer Efficiency combined with estimated emissions. European regions and the Orient including China have a high potential to contribute a-HCH contamination in the Arctic due to high rates of emission in these regions despite low Transfer Efficiencies. Sensitivity analyses reveal that the performance and reliability of the model is strongly in.uenced by parameters controlling degradation rates.

}, year = {2004}, journal = {Environmental Pollution}, volume = {128}, number = {1-2}, pages = {223-240}, month = {03/2004}, doi = {10.1016/j.envpol.2003.08.037}, language = {eng}, }