Abstract
Variational algorithms for strongly correlated chemical and materials systems are one of the most promising applications of near-term quantum computers. We present an extension to the variational quantum eigensolver that approximates the ground state of a system by solving a generalized eigenvalue problem in a subspace spanned by a collection of parametrized quantum states. This allows for the systematic improvement of a logical wavefunction ansatz without a significant increase in circuit complexity. To minimize the circuit complexity of this approach, we propose a strategy for efficiently measuring the Hamiltonian and overlap matrix elements between states parametrized by circuits that commute with the total particle number operator. This strategy doubles the size of the state preparation circuits but not their depth, while adding a small number of additional two-qubit gates relative to standard variational quantum eigensolver. We also propose a classical Monte Carlo scheme to estimate the uncertainty in the ground state energy caused by a finite number of measurements of the matrix elements. We explain how this Monte Carlo procedure can be extended to adaptively schedule the required measurements, reducing the number of circuit executions necessary for a given accuracy. We apply these ideas to two model strongly correlated systems, a square configuration of H4 and the π-system of hexatriene (C6H8).
Highlights
Large, error-corrected quantum computers are expected to provide powerful new tools for understanding quantum many-body physics
In the case of k = 1 we observe that we can systematically improve the accuracy of the estimated ground state energy by increasing the number of states included in the NOVQE subspace (M)
We have introduced an extension to the variational quantum eigensolver that calls for the ground state energy to be approximated by solving a generalized eigenvalue problem in a subspace that is spanned by a linear combination of M parametrized quantum wavefunctions
Summary
Error-corrected quantum computers are expected to provide powerful new tools for understanding quantum many-body physics. Such devices will be able to efficiently simulate long-time dynamics [1], and through phase estimation, measure the energy of a trial wavefunction while projecting it into the eigenbasis of the Hamiltonian [2]. The variational quantum eigensolver (VQE) [3, 4], uses a potentially noisy quantum computer as a black box to prepare parametrized wavefunctions and measure their energy. We shall present a new approach in this latter direction that allows for a systematic increase in wavefunction complexity without a growing circuit depth
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