Quantum Markov Chain Monte Carlo with Digital Dissipative Dynamics on Quantum Computers
Abstract
Modeling the dynamics of a quantum system connected to the environment is critical for advancing our understanding of complex quantum processes, as most quantum processes in nature are affected by an environment. Modeling a macroscopic environment on a quantum simulator may be achieved by coupling independent ancilla qubits that facilitate energy exchange in an appropriate manner with the system and mimic an environment. This approach requires a large, and possibly exponential number of ancillary degrees of freedom which is impractical. In contrast, we develop a digital quantum algorithm that simulates interaction with an environment using a small number of ancilla qubits. By combining periodic modulation of the ancilla energies, or spectral combing, with periodic reset operations, we are able to mimic interaction with a large environment and generate thermal states of interacting many-body systems. We evaluate the algorithm by simulating preparation of thermal states of the transverse Ising model. Our algorithm can also be viewed as a quantum Markov chain Monte Carlo (QMCMC) process that allows sampling of the Gibbs distribution of a multivariate model. To demonstrate this we evaluate the accuracy of sampling Gibbs distributions of simple probabilistic graphical models using the algorithm.
Cite
@article{arxiv.2103.03207,
title = {Quantum Markov Chain Monte Carlo with Digital Dissipative Dynamics on Quantum Computers},
author = {Mekena Metcalf and Emma Stone and Katherine Klymko and Alexander F. Kemper and Mohan Sarovar and Wibe A. de Jong},
journal= {arXiv preprint arXiv:2103.03207},
year = {2021}
}