Bang-bang algorithms for quantum many-body ground states: a tensor network exploration
Abstract
We use matrix product techniques to investigate the performance of two algorithms for obtaining the ground state of a quantum many-body Hamiltonian H = HA + HB in infinite systems. The first algorithm is a generalization of the quantum approximate optimization algorithm (QAOA) and uses a quantum computer to evolve an initial product state into an approximation of the ground state of H, by alternating between HA and HB. We show for the 1D quantum Ising model that the accuracy in representing a gapped ground state improves exponentially with the number of alternations. The second algorithm is the variational imaginary time ansatz (VITA), which uses a classical computer to simulate the ground state via alternating imaginary time steps with HA and HB. We find for the 1D quantum Ising model that an accurate approximation to the ground state is obtained with a total imaginary time τ that grows only logarithmically with the inverse energy gap 1/ of H. This is much faster than imaginary time evolution by H, which would require τ 1/ .
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