Quantum Entanglement and the Growth of Laplacian Eigenfunctions

TL;DR

This paper investigates the growth of Laplacian eigenfunctions on manifolds, proposing a mechanism explaining slow growth in generic cases and revealing quantum entanglement phenomena related to eigenfunction correlations.

Contribution

It introduces a new explanation for eigenfunction growth rates on generic manifolds and uncovers quantum entanglement phenomena among eigenfunctions at different points.

Findings

Eigenfunction growth on generic manifolds is typically logarithmic in eigenvalue.

A mechanism involving spectral projectors explains slow growth behavior.

Existence of points with correlated eigenfunction sequences indicates quantum entanglement.

Abstract

We study the growth of Laplacian eigenfunctions $ -\Delta \phi_k = \lambda_k \phi_k$ on compact manifolds $(M,g)$. H\"ormander proved sharp polynomial bounds on $\| \phi_k\|_{L^{\infty}}$ which are attained on the sphere. On a `generic' manifold, the behavior seems to be different: both numerics and Berry's random wave model suggest $\| \phi_k\|_{L^{\infty}} \lesssim \sqrt{\log{\lambda_k}}$ as the typical behavior. We propose a mechanism, centered around an $L^1-$analogue of the spectral projector, for explaining the slow growth in the generic case: for $\phi_{n+1}(x_0)$ to be large, it is necessary that either (1) several of the first $n$ eigenfunctions were large in $x_0$ or (2) that $\phi_{n+1}$ is strongly correlated with a suitable linear combination of the first $n$ eigenfunctions on most of the manifold or (3) both. An interesting byproduct is quantum entanglement for Laplacian eigenfunctions: the existence of two distinct points $x,y \in M$ such that the sequences $(\phi_k(x))_{k=1}^{\infty}$ and $(\phi_k(y))_{k=1}^{\infty}$ do not behave like independent random variables. The existence of such points is not to be expected for generic manifolds but common for the classical manifolds and subtly intertwined with eigenfunction concentration.