English

Quantum trajectories for time-dependent adiabatic master equations

Quantum Physics 2024-01-17 v2

Abstract

We describe a quantum trajectories technique for the unraveling of the quantum adiabatic master equation in Lindblad form. By evolving a complex state vector of dimension NN instead of a complex density matrix of dimension N2N^2, simulations of larger system sizes become feasible. The cost of running many trajectories, which is required to recover the master equation evolution, can be minimized by running the trajectories in parallel, making this method suitable for high performance computing clusters. In general, the trajectories method can provide up to a factor NN advantage over directly solving the master equation. In special cases where only the expectation values of certain observables are desired, an advantage of up to a factor N2N^2 is possible. We test the method by demonstrating agreement with direct solution of the quantum adiabatic master equation for 88-qubit quantum annealing examples. We also apply the quantum trajectories method to a 1616-qubit example originally introduced to demonstrate the role of tunneling in quantum annealing, which is significantly more time consuming to solve directly using the master equation. The quantum trajectories method provides insight into individual quantum jump trajectories and their statistics, thus shedding light on open system quantum adiabatic evolution beyond the master equation.

Keywords

Cite

@article{arxiv.1710.03431,
  title  = {Quantum trajectories for time-dependent adiabatic master equations},
  author = {Ka Wa Yip and Tameem Albash and Daniel A. Lidar},
  journal= {arXiv preprint arXiv:1710.03431},
  year   = {2024}
}

Comments

18 pages, 8 figures; v2: Phys. Rev. A version

R2 v1 2026-06-22T22:08:25.784Z