A variational lower bound on the ground state of a many-body system and the squaring parametrization of density matrices

Abstract

A variational upper bound on the ground state energy E gs of a quantum system, E gs ≤slant |H| , is well-known (here H is the Hamiltonian of the system and is an arbitrary wave function). Much less known are variational lower bounds on the ground state. We consider one such bound which is valid for a many-body translation-invariant lattice system. Such a lattice can be divided into clusters which are identical up to translations. The Hamiltonian of such a system can be written as H=Σi=1M Hi, where a term Hi is supported on the i'th cluster. The bound reads E gs≥slant M ∈f_cl ∈ SclG trclcl \, Hcl , where SclG is some wisely chosen set of reduced density matrices of a single cluster. The implementation of this latter variational principle can be hampered by the difficulty of parameterizing the set M, which is a necessary prerequisite for a variational procedure. The root cause of this difficulty is the nonlinear positivity constraint >0 which is to be satisfied by a density matrix. The squaring parametrization of the density matrix, =τ2/ tr\,τ2, where τ is an arbitrary (not necessarily positive) Hermitian operator, accounts for positivity automatically. We discuss how the squaring parametrization can be utilized to find variational lower bounds on ground states of translation-invariant many-body systems. As an example, we consider a one-dimensional Heisenberg antiferromagnet.