Finite Size Scaling for Criticality of the Schr\"odinger Equation

TL;DR

This paper discusses finite size scaling methods, including finite element and basis set expansion, to accurately predict critical parameters for the stability of quantum systems near the bound-continuum threshold.

Contribution

It introduces two finite size scaling techniques for estimating critical parameters in quantum Hamiltonians, enhancing stability predictions of quantum systems.

Findings

Finite size scaling effectively predicts critical parameters.

Finite element and basis set expansion methods are efficient.

Accurate estimation of stability thresholds in quantum systems.

Abstract

By solving the Schr\"odinger equation one obtains the whole energy spectrum, both the bound and the continuum states. If the Hamiltonian depends on a set of parameters, these could be tuned to a transition from bound to continuum states. The behavior of systems near the threshold, which separates bound-states from continuum states, is important in the study of such phenomenon as: ionization of atoms and molecules, molecule dissociation, scattering collisions and stability of matter. In general, the energy is non-analytic as a function of the Hamiltonian parameters or a bound-state does not exist at the threshold energy. The overall goal of this chapter is to show how one can predict, generate and identify new class of stable quantum systems using large-dimensional models and the finite size scaling approach. Within this approach, the finite size corresponds not to the spatial dimension but to the number of elements in a complete basis set used to expand the exact eigenfunction of a given Hamiltonian. This method is efficient and very accurate for estimating the critical parameters, $\{\lambda_i\}$, for stability of a given Hamiltonian, $H(\lambda_i)$. We present two methods of obtaining critical parameters using finite size scaling for a given quantum Hamiltonian: The finite element method and the basis set expansion method.