Approximate quantum and acoustic cloaking
Abstract
At any energy E > 0, we construct a sequence of bounded potentials , supported in an annular region in three-space, which act as approximate cloaks for solutions of Schr\"odinger's equation: For any potential such that E is not a Neumann eigenvalue of in , the scattering amplitudes as . The thus not only form a family of approximately transparent potentials, but also function as approximate invisibility cloaks in quantum mechanics. On the other hand, for close to interior eigenvalues, resonances develop and there exist {\it almost trapped states} concentrated in . We derive the from singular, anisotropic transformation optics-based cloaks by a de-anisotropization procedure, which we call \emph{isotropic transformation optics}. This technique uses truncation, inverse homogenization and spectral theory to produce nonsingular, isotropic approximate cloaks. As an intermediate step, we also obtain approximate cloaking for a general class of equations including the acoustic equation.
Cite
@article{arxiv.0812.1706,
title = {Approximate quantum and acoustic cloaking},
author = {Allan Greenleaf and Yaroslav Kurylev and Matti Lassas and Gunther Uhlmann},
journal= {arXiv preprint arXiv:0812.1706},
year = {2008}
}
Comments
2 color figures