Traditional computational methods for studying quantum many-body systems are
"forward methods," which take quantum models, i.e., Hamiltonians, as input and
produce ground states as output. However, such forward methods often limit
one's perspective to a small fraction of the space of possible Hamiltonians. We
introduce an alternative computational "inverse method," the
Eigenstate-to-Hamiltonian Construction (EHC), that allows us to better
understand the vast space of quantum models describing strongly correlated
systems. EHC takes as input a wave function ∣ψT⟩ and produces as
output Hamiltonians for which ∣ψT⟩ is an eigenstate. This is
accomplished by computing the quantum covariance matrix, a quantum mechanical
generalization of a classical covariance matrix. EHC is widely applicable to a
number of models and in this work we consider seven different examples. Using
the EHC method, we construct a parent Hamiltonian with a new type of
antiferromagnetic ground state, a parent Hamiltonian with two different
targeted degenerate ground states, and large classes of parent Hamiltonians
with the same ground states as well-known quantum models, such as the
Majumdar-Ghosh model, the XX chain, the Heisenberg chain, the Kitaev chain, and
a 2D BdG model.Comment: 13 pages, 7 figures, 1 table; new example in results section; updated
supplement; additional references; other minor change