Magnetic Dipole Absorption of Radiation in Small Conducting Particles
arXiv:cond-mat/9709075 · doi:10.1088/0953-8984/10/12/013
Abstract
We give a theoretical treatment of magnetic dipole absorption of electromagnetic radiation in small conducting particles, at photon energies which are large compared to the single particle level spacing, and small compared to the plasma frequency. We discuss both diffusive and ballistic electron dynamics for particles of arbitrary shape. The conductivity becomes non-local when the frequency is smaller than the frequency Ï_c characterising the transit of electrons from one side of the particle to the other, but in the diffusive case Ï_c plays no role in determining the absorption coefficient. In the ballistic case, the absorption coefficient is proportional to Ï^2 for Ï<< Ï_c, but is a decreasing function of Ïfor Ï>> Ï_c.
25 pages of plain TeX, 2 postscipt figures