Characterizing the parent Hamiltonian for a complete set of orthogonal wave functions: An inverse quantum problem

TL;DR

This paper explores the inverse problem of constructing Hamiltonians from orthogonal wave functions in quantum spin systems, revealing how wave functions and spectra influence Hamiltonian structure and potential quantum engineering applications.

Contribution

It introduces a method to derive local and nonlocal Hamiltonians from complete sets of wave functions, highlighting the impact of energy spectra on Hamiltonian interactions.

Findings

Complete product states lead to local Hamiltonians.

Tree wave functions result in nonlocal Hamiltonians.

Energy spectra significantly influence Hamiltonian interactions.

Abstract

We study the inverse problem of constructing an appropriate Hamiltonian from a physically reasonable set of orthogonal wave functions for a quantum spin system. Usually, we are given a local Hamiltonian and try to characterize the relevant wave functions and energies (the spectrum) of the system. Here, we take the opposite approach; starting from a collection of orthogonal wave functions, our goal is to characterize the associated parent Hamiltonian, to see how the wave functions and the energy values determine the structure of the parent Hamiltonian. Specifically, we obtain (quasi) local Hamiltonians by a complete set of (multilayer) product states and a local mapping of the energy values to the wave functions. On the other hand, a complete set of tree wave functions (having a tree structure) results to nonlocal Hamiltonians and operators which flip simultaneously all the spins in a single branch of the tree graph. We observe that even for a given set of wave functions, the energy spectrum can significantly change the nature of interactions in the Hamiltonian. These effects can be exploited in a quantum engineering problem optimizing an objective functional of the Hamiltonian.