论文信息 - A Mathematical model for oil slick transport and mixing in rivers

A Mathematical model for oil slick transport and mixing in rivers

Abstract : The growing concern over the impacts of oil spills on aquatic environments has led to the development of many computer models for simulating the transport and spreading of oil slicks in surface waters. Almost all of these models were developed for coastal environments. A few river models exist. These models only considered the movement of surface oil slicks. In this study a two- layer model, ROSS2, is developed for simulating oil spills in rivers. This model considers the oil in the river to consist of a surface slick and suspended oil droplets entrained over the depth of the flow. The oil transformation processes considered in the model include advection, mechanical spreading, turbulent diffusion and mixing, evaporation, dissolution, emulsification, shoreline deposition and sinking. The model can be used for simulating instantaneous or continuous spills either on or under the water surface in rivers with or without an ice cover. The model has been implemented for the Ohio-Monongahela-Allegheny river system and the upper St. Lawrence River. This report describes the model formulation and implementation. A case study is presented along with detailed explanations of the program structure and its input and output. Although it is developed for simulating oil spills, the model can be applied to spills of other hazardous materials. Computer models, Oil spills, Oil slicks, Rivers.

[1] Stephen C. Hung. Seaway Emergency Response Plan , 1991 .

[2] W. W. Sayre,et al. A LABORATORY INVESTIGATION OF OPEN CHANNEL DISPERSION PROCESSES FOR DISSOLVED, SUSPENDED, AND FLOATING DISPERSANTS , 1968 .

[3] A. Katz,et al. A PRELIMINARY ASSESSMENT OF THE ENVIRONMENTAL VULNERABILITY OF MACHIAS BAY, MAINE TO OIL SUPERTANKERS , 1973 .

[4] James C. Huang,et al. A REVIEW OF THE STATE-OF-THE-ART OF OIL SPILL FATE/BEHAVIOR MODELS , 1983 .

[5] S. N. Milford,et al. Eulerian‐Lagrangian Solution of the Convection‐Dispersion Equation in Natural Coordinates , 1984 .

[6] Poojitha D. Yapa,et al. OIL SLICK TRANSPORT IN RIVERS , 1988 .

[7] M. Hayes,et al. VULNERABILITY OF COASTAL ENVIRONMENTS TO OIL SPILL IMPACTS , 1978 .

[8] M. Spaulding. A state-of-the-art review of oil spill trajectory and fate modeling* , 1988 .

[9] Torstein K. Fannelop,et al. DYNAMICS OF OIL SLICKS , 1972 .

[10] Ole Secher Madsen,et al. A REVIEW AND EVALUATION OF BASIC TECHNIQUES FOR PREDICTING THE BEHAVIOR OF SURFACE OIL SLICKS , 1977 .

[11] D. T. Tsahalis. Theoretical and Experimental Study of Wind- and Wave-Induced Drift , 1979 .

[12] H. Fischer. Mixing in Inland and Coastal Waters , 1979 .

[13] L. A. Schultz,et al. THE CONTAINMENT OF OIL SPILLED UNDER ROUGH ICE , 1981 .

[14] J. Fay. The Spread of Oil Slicks on a Calm Sea , 1969 .

[15] J. Fay. Physical Processes in the Spread of Oil on a Water Surface , 1971 .