Problem-tailored Simulation of Energy Transport on Noisy Quantum Computers

TL;DR

This paper demonstrates quantum hardware simulations of energy transport in a many-body system, using problem-specific sampling and error mitigation to achieve results comparable to ideal simulations despite hardware noise.

Contribution

It introduces a problem-tailored sampling basis and a renormalization error mitigation strategy for simulating quantum transport on noisy quantum computers.

Findings

Successful simulation of energy transport with 90 Trotter steps on hardware

Identification of the Pauli Y basis as an efficient sampling basis

Development of a variational method for basis optimization

Abstract

The transport of conserved quantities like spin and charge is fundamental to characterizing the behavior of quantum many-body systems. Numerically simulating such dynamics is generically challenging, which motivates the consideration of quantum computing strategies. However, the relatively high gate errors and limited coherence times of today's quantum computers pose their own challenge, highlighting the need to be frugal with quantum resources. In this work we report simulations on quantum hardware of infinite-temperature energy transport in the mixed-field Ising chain, a paradigmatic many-body system that can exhibit a range of transport behaviors at intermediate times. We consider a chain with $L=12$ sites and find results broadly consistent with those from ideal circuit simulators over 90 Trotter steps, containing up to 990 entangling gates. To obtain these results, we use two key problem-tailored insights. First, we identify a convenient basis$\unicode{x2013}$the Pauli $Y$ basis$\unicode{x2013}$in which to sample the infinite-temperature trace and provide theoretical and numerical justifications for its efficiency relative to, e.g., the computational basis. Second, in addition to a variety of problem-agnostic error mitigation strategies, we employ a renormalization strategy that compensates for global nonconservation of energy due to device noise. We discuss the applicability of the proposed sampling approach beyond the mixed-field Ising chain and formulate a variational method to search for a sampling basis with small sample-to-sample fluctuations for an arbitrary Hamiltonian. This opens the door to applying these techniques in more general models.