Exponential Localization for Eigensections of the Bochner–Schrödinger operator

IF 1.7 3区物理与天体物理 Q2 PHYSICS, MATHEMATICAL Russian Journal of Mathematical Physics Pub Date : 2024-10-03 DOI:10.1134/S1061920824030099

Yu.A. Kordyukov

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Abstract

We study asymptotic spectral properties of the Bochner–Schrödinger operator \(H_{p}=\frac 1p\Delta^{L^p\otimes E}+V\) on high tensor powers of a Hermitian line bundle \(L\) twisted by a Hermitian vector bundle \(E\) on a Riemannian manifold \(X\) of bounded geometry under the assumption that the curvature form of \(L\) is nondegenerate. At an arbitrary point \(x_0\) of \(X\), the operator \(H_p\) can be approximated by a model operator \(\mathcal H^{(x_0)}\), which is a Schrödinger operator with constant magnetic field. For large \(p\), the spectrum of \(H_p\) asymptotically coincides, up to order \(p^{-1/4}\), with the union of the spectra of the model operators \(\mathcal H^{(x_0)}\) over \(X\). We show that, if the union of the spectra of \(\mathcal H^{(x_0)}\) over the complement of a compact subset of \(X\) has a gap, then the spectrum of \(H_{p}\) in the gap is discrete, and the corresponding eigensections decay exponentially away from a compact subset.

DOI 10.1134/S1061920824030099

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波赫纳-薛定谔算子等差数列的指数定位

我们研究了在有界几何的黎曼流形\(X\)上由赫米向量束\(E\)扭转的赫米线束\(L\)的高张量幂上波赫纳-薛定谔算子\(H_{p}=\frac 1p\Delta^{L^p\otimes E}+V\)的渐近谱性质，前提是\(L\)的曲率形式是非退化的。在 \(X\) 的任意点 \(x_0\) 上，算子 \(H_p\) 可以用一个模型算子 \(\mathcal H^{(x_0)}\) 来近似，它是一个具有恒定磁场的薛定谔算子。对于大的\(p\)，\(H_p\)的频谱与模型算子在\(X\)上的\(\mathcal H^{(x_0)}\) 的频谱的联集近似重合，直到秩\(p^{-1/4}\)。我们证明，如果 \(\mathcal H^{(x_0)}\) 在 \(X\) 紧凑子集的补集上的谱（union of the spectra of \(\mathcal H^{(x_0)}\) over the complement of a compact subset of \(X\) ）有一个缺口，那么缺口中的\(H_{p}\)谱是离散的，并且相应的eigensections在远离紧凑子集时呈指数衰减。 doi 10.1134/s1061920824030099

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来源期刊

Russian Journal of Mathematical Physics 物理-物理：数学物理

CiteScore

3.10

自引率

14.30%

发文量

审稿时长

>12 weeks

期刊介绍： Russian Journal of Mathematical Physics is a peer-reviewed periodical that deals with the full range of topics subsumed by that discipline, which lies at the foundation of much of contemporary science. Thus, in addition to mathematical physics per se, the journal coverage includes, but is not limited to, functional analysis, linear and nonlinear partial differential equations, algebras, quantization, quantum field theory, modern differential and algebraic geometry and topology, representations of Lie groups, calculus of variations, asymptotic methods, random process theory, dynamical systems, and control theory.