|Title||Monitoring-induced Entanglement Entropy and Sampling Complexity|
|Publication Type||Journal Article|
|Year of Publication||2022|
|Authors||Van Regemortel, M, Shtanko, O, García-Pintos, LPedro, Deshpande, A, Dehghani, H, Gorshkov, AV, Hafezi, M|
|Keywords||FOS: Physical sciences, Quantum Physics (quant-ph)|
The dynamics of open quantum systems is generally described by a master equation, which describes the loss of information into the environment. By using a simple model of uncoupled emitters, we illustrate how the recovery of this information depends on the monitoring scheme applied to register the decay clicks. The dissipative dynamics, in this case, is described by pure-state stochastic trajectories and we examine different unravelings of the same master equation. More precisely, we demonstrate how registering the sequence of clicks from spontaneously emitted photons through a linear optical interferometer induces entanglement in the trajectory states. Since this model consists of an array of single-photon emitters, we show a direct equivalence with Fock-state boson sampling and link the hardness of sampling the outcomes of the quantum jumps with the scaling of trajectory entanglement.