Leontovich boundary condition
The Leontovich boundary condition is a classical electrodynamics boundary condition that relates to the tangential components of the electric Et and magnetic Ht fields on the surface of well-conducting bodies.[1][2]
Definition
As originally formulated by Russian physicist Mikhail Leontovich, the boundary condition is given as
where and represent the tangential components of the electric and magnetic fields, is the effective surface impedance, and is a unit normal pointing into the conducting material.[1] This condition is accurate when the permittivity of the conductor is large, which is the case for most metals. More generally, for cases when the radii of curvature of the conducting surface is large with respect to the skin depth, the resulting fields on the interior can be well approximated by plane waves, thus giving rise to the Leontovitch condition.[1][3]
Applications
The Leontovich boundary condition is useful in many scattering problems where one material is a metal with large (but finite) conductivity. As the condition provides a relationship between the electric and magnetic fields at the surface of the conductor, without knowledge of the fields within, the task of finding the total fields is considerably simplified.
References
- Landau, L. D.; Lifshitz, E. M. (1984). Electrodynamics of Continuous Media, Volume 8 (2nd ed.). Pergamon. ISBN 978-0750626347.
- M. A. Leontovich, On the approximate boundary conditions for the electromagnetic field on the surface of well conducting bodies. Moscow: Academy of Sciences of USSR, 1948.
- Senior, T. B. A. (1960). "Impedance boundary conditions for imperfectly conducting surfaces". Appl. Sci. Res. 8: 418.