📝 SummarXiv

Abstract

A quantum system may undergo undesired dynamics if it is already correlated with its environment before global unitary evolution takes place. To mitigate these effects, we apply local operations on the system of interest prior to the global evolution. This ensures that a specific dynamics-matching condition is satisfied - namely, that the system's dynamics can be U-generated starting from an initial product state. We review two strategies for achieving this: local measurements and local unitaries. For each, we outline their respective advantages and disadvantages and provide examples illustrating when the dynamics-matching condition can be satisfied. Since most operations inevitably alter the system's initial state, we optimize the fidelity between the original system state and the post-operation state, ensuring the condition can be met with minimal perturbation. Local measurements always guarantee that the system dynamics can be U-generated from a product state, but this comes at the cost of reduced fidelity. By contrast, local unitary transformations typically avoid this loss of fidelity: in our numerical study of 402 cases, they succeeded in nearly all instances, with a minimum fidelity of about 94.2%. We further strengthen these results by showing that a single unitary operation can prevent all non-completely positive quantum dynamics for a system and environment undergoing time-dependent global evolution. Moreover, we demonstrate that a general two-term Kraus channel - implementable with the addition of just one qubit - can raise all fidelities to 1 across the 402 cases, while still ensuring that the dynamics-matching condition is satisfied.