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다국어 초록 (Multilingual Abstract)

In this study, analytical solution of multip-species transport equations coupled with a first-order reaction network under constant concentration boundary condition or total flux boundary condition is obtained using similarity transformation approach of Clement et al. (2000). The study shows the schematic process about how multi-species transport equations with first-order sequential reaction network is transformed through the similarity transformation approach into independent and uncoupled single species transport equations with first-order reaction. The analytical solution was verified through the comparison with popular commercial programs such as 2DFATMIC and RT3D. The analytical solution can be utilized in nuclear waste sites where radioactive contaminants and their daughter products occur and in industrial complex cities where chlorinated solvent such as PCE, TCE, and its biodegradation products produces. In addition, it can help the verification of the developed numerical code.

참고문헌 (Reference)

1 Clement, T.P., "RT3D v2.5: A Modular Computer code for Simulating Reactive Multi-species Transport in 3-Dimensional groundwater systems. Pacific Northwest National Laboratory, Rihland, WA 99352, USA, PNNL-SA-11720"

2 Chilakapati, A., "Nonlinear reactions and nonuniform flows" 35 (35): 2427-2438, 1999

3 Clement, T.P., "Natural attenuation of chlorinated ethene compounds:model development and field-scale application" 42 : 113-140, 2000

4 Zheng, C., "MT3DMS: A modular threedimensional multispecies model for simulation of advection, dispersion and chemical reactions of contaminants in groundwater systems; Documentation and User's Guide" Army Engineer Research and Development Center 1999

5 Bear, J., "Hydraulics of Groundwater" McGraw-Hill, Inc 268-269, 1979

6 Clement, T.P., "Generalized solution to multispecies transport equations coupled with a first-order reaction network" 37 (37): 157-163, 2001

7 Manoranjan, V., "Exact solution for contaminant transport with kinetic Langmuir sorption" 32 : 749-752, 1996

8 Sun, Y., "Development of analytical solutions for multiple-species transport with serial and parallel reactions" 35 (35): 185-190, 1999

9 Lunn, M., "Determining analytic solution of multiple species contaminant transport, with sorption and decay" 180 : 195-210, 1996

10 van Genuchten, M.T., "Convextive-dispersive transport of solutes involved in sequential first-order decay reactions" 11 (11): 129-147, 1985