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A Positivity-Preserving Scheme for the Simulation of Streamer Discharges in Non-Attaching and Attaching Gases

Published online by Cambridge University Press:  03 June 2015

Chijie Zhuang
Affiliation:
State Key Lab of Power Systems, Department of Electrical Engineering, Tsinghua University, Beijing 100084, China
Rong Zeng*
Affiliation:
State Key Lab of Power Systems, Department of Electrical Engineering, Tsinghua University, Beijing 100084, China
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Abstract

Assumed having axial symmetry, the streamer discharge is often described by a fluid model in cylindrical coordinate system, which consists of convection dominated (diffusion) equations with source terms, coupled with a Poisson’s equation. Without additional care for a stricter CFL condition or special treatment to the negative source term, popular methods used in streamer discharge simulations, e.g., FEM-FCT, FVM, cannot ensure the positivity of the particle densities for the cases in attaching gases. By introducing the positivity-preserving limiter proposed by Zhang and Shu [15] and Strang operator splitting, this paper proposes a finite difference scheme with a provable positivity-preserving property in cylindrical coordinate system, for the numerical simulation of streamer discharges in non-attaching and attaching gases. Numerical examples in non-attaching gas (N2) and attaching gas (SF6) are given to illustrate the effectiveness of the scheme.

Type
Research Article
Copyright
Copyright © Global Science Press Limited 2014

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References

[1] Ebert, U., Nijdam, S., Li, C., et al. Review of recent results on streamer discharges and their relevance for sprites and lightning. Journal of Geophysical Research, 2010, 115(A2): A00E43.Google Scholar
[2] Montijn, C., Hundsdorfer, W. and Ebert, U. An adaptive grid refinement strategy for the simulation of negative streamers. Journal of Computational Physics, 2006 219(2): 801835.Google Scholar
[3] Morrow, R. Space-chargeeffectsin high-density plasmas. Journal of Computational Physics, 1982 46(3): 454461.Google Scholar
[4] Georghiou, G., Morrow, R., Metaxas, A. A two-dimensional, finite-element, flux-corrected transport algorithm for the solution of gas discharge problems. Journal of Physics D: Applied Physics, 2000 33(19): 24532466.CrossRefGoogle Scholar
[5] Min, W., Kim, H., Lee, S., et al. An investigation of FEM-FCT method for streamer corona Simulation. IEEE Transactions on Magnetics, 2000 36(4): 12801284.Google Scholar
[6] Boris, J., Book, D. Flux-corrected transport I: SHASTA, a fluid transport algorithm that works. Journal of Computational Physics, 1973 11(1): 3869.Google Scholar
[7] Zalezak, S. Fully multidimensional flux-corrected transport algorithms for fluids. Journal of Computational Physics, 31(11): 335362 (1979).Google Scholar
[8] Lohner, R., Morgan, K., Vahdati, M., et al. FEM-FCT: combining unstructured grids with high resolution. Communications in Applied Numerical Methods, 4(6): 717730 (1988).Google Scholar
[9] Bessieres, D., Paillol, J., Bourdon, A., et al. A new one-dimensional moving mesh method applied to the simulation of streamer discharges. Journal of Physics D: Applied Physics, 40: 65596570 (2007).Google Scholar
[10] Pancheshnyi, S., Segur, P., Capeilleŕe, J., et al. Numerical simulation of filamentary discharges with parallel adaptive mesh refinement. Journal of Computational Physics, 227: 65746590 (2008).CrossRefGoogle Scholar
[11] Swarztrauber, P. The methods of cyclic reduction, Fourier analysis and the FACR algorithm for the discrete solution of Poisson’s equation on a rectangle. SIAM Review, 19(3): 490501 (1977).CrossRefGoogle Scholar
[12] Bourdon, A., Bessieres, D., Paillol, J., et al. Influence of numerical schemes on positive streamer propagation. Proceedings of 15th Internal Conference on Gas Discharges and their Applications, Toulouse, France, 2004.Google Scholar
[13] Strang, G. On the construction and comparison of difference schemes. SIAM Journal on Numerical Analysis, 5(3): 506517 (1968).Google Scholar
[14] Shu, C. W. Essentially Non-Oscillatory and Weighted Essentially Non-Oscillatory schemes for hyperbolic conservation laws. in: Advanced Numerical Approximation of Nonlinear Hyperbolic Equations (Lecture Notes in Mathematics), 1697: 325432 (1998).CrossRefGoogle Scholar
[15] Zhang, X. and Shu, C.W. Positivity-preserving high order finite difference WENO schemes for compressible Euler equations. Journal of Computational Physics, 231(5): 22452258 (2012).Google Scholar
[16] Zhang, X. and Shu, C.W. On maximum-principle-satisfying high order schemes for scalar conservation laws. Journal of Computational Physics, 229(1): 30913120 (2010).Google Scholar
[17] Zhang, X. Maximum-principle-satisfying and positivity-preserving high order schemes for conservation laws. PhD Thesis, RI: Brown University, 2011.Google Scholar
[18] Zhang, X. and Shu, C.W. Maximum-principle-satisfying and positivity-preserving high order schemes for conservation laws: survey and new developments. Proceedings of the Royal Society A, 467: 27522776 (2011).Google Scholar
[19] Shu, C.W. Total-variation-diminishing time discretizations. SIAM Journal on Scientific and Statical Computing, 9(6): 10731084 (1988).Google Scholar
[20] Dhali, S. and Williams, P. Numerical simulation of streamer propagation in nitrogen at atmospheric pressure. Physical Review A, 31(2): 12191222 (1985).Google Scholar
[21] Dhali, S. and Williams, P. Two dimensional studies of streamers in gases. Journal of Applied Physics, 62, 4696 (1987).Google Scholar
[22] Ducasse, O., Papageorghiou, L., Eichwald, O., et al. Critical analysis on two-dimensional point-to-plane streamer simulations using the finite element and finite volume methods. IEEE Transactions on Plasma Science, 35(5): 12871300 (2007).Google Scholar
[23] Sweby, P. High resolution schemes using flux limiters for hyperbolic conservation laws. SIAM Journal on Numerical Analysis, 21(5): 9951011 (1984).Google Scholar