English

Creating desired potentials by embedding small inhomogeneities

Mathematical Physics 2015-05-13 v1 math.MP

Abstract

The governing equation is [2+k2q(x)]u=0[\nabla^2+k^2-q(x)]u=0 in R3\R^3. It is shown that any desired potential q(x)q(x), vanishing outside a bounded domain DD, can be obtained if one embeds into D many small scatterers qm(x)q_m(x), vanishing outside balls Bm:={x:xxm<a}B_m:=\{x: |x-x_m|<a\}, such that qm=Amq_m=A_m in BmB_m, qm=0q_m=0 outside BmB_m, 1mM1\leq m \leq M, M=M(a)M=M(a). It is proved that if the number of small scatterers in any subdomain Δ\Delta is defined as N(Δ):=xmΔ1N(\Delta):=\sum_{x_m\in \Delta}1 and is given by the formula N(Δ)=V(a)1Δn(x)dx[1+o(1)]N(\Delta)=|V(a)|^{-1}\int_{\Delta}n(x)dx [1+o(1)] as a0a\to 0, where V(a)=4πa3/3V(a)=4\pi a^3/3, then the limit of the function uM(x)u_{M}(x), lima0UM=ue(x)\lim_{a\to 0}U_M=u_e(x) does exist and solves the equation [2+k2q(x)]u=0[\nabla^2+k^2-q(x)]u=0 in R3\R^3, where q(x)=n(x)A(x)q(x)=n(x)A(x),and A(xm)=AmA(x_m)=A_m. The total number MM of small inhomogeneities is equal to N(D)N(D) and is of the order O(a3)O(a^{-3}) as a0a\to 0. A similar result is derived in the one-dimensional case.

Keywords

Cite

@article{arxiv.0906.3214,
  title  = {Creating desired potentials by embedding small inhomogeneities},
  author = {A. G. Ramm},
  journal= {arXiv preprint arXiv:0906.3214},
  year   = {2015}
}
R2 v1 2026-06-21T13:14:23.386Z