Variational preparation of finite-temperature states on a quantum computer

The preparation of thermal equilibrium states is important for the simulation of condensed matter and cosmology systems using a quantum computer. We present a method to prepare such mixed states with unitary operators and demonstrate this technique experimentally using a gate-based quantum processor. Our method targets the generation of thermofield double states using a hybrid quantum-classical variational approach motivated by quantum-approximate optimization algorithms, without prior calculation of optimal variational parameters by numerical simulation. The fidelity of generated states to the thermal-equilibrium state smoothly varies from 99 to 75% between infinite and near-zero simulated temperature, in quantitative agreement with numerical simulations of the noisy quantum processor with error parameters drawn from experiment.

Automated summary

This study introduces a method for preparing mixed thermal equilibrium states using a quantum processor, achieving fidelity ranging from 99% to 75%. The generated states smoothly transition between infinite and near-zero simulated temperature, in quantitative agreement with numerical simulations of the noisy quantum processor.