Optimal Zeno Dragging for Quantum Control: A Shortcut to Zeno with Action-Based Scheduling Optimization

Lewalle, Philippe; Zhang, Yipei; Whaley, K. Birgitta

doi:10.1103/prxquantum.5.020366

Cited by 3 publications

(1 citation statement)

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“…Here we take advantage of this continuous evolution to develop a path integral formulation of the measurement-induced closed geometric phases, associated with the set of self-closing quantum trajectories. In particular, we will follow the approach developed by Chantasri-Dressel-Jordan (CDJ) for continuous Gaussian measurements [42][43][44][45], which is a wellestablished technique for investigating continuous measurement dynamics [46][47][48][49]. By incorporating a phase variable in the CDJ action for continuous Gaussian measurements we obtain a path-integral formulation for open and closed geometric phases.…”

Section: Introductionmentioning

confidence: 99%

Action formalism for geometric phases from self-closing quantum trajectories

Shea,

Romito

2024

J. Phys. A: Math. Theor.

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When subject to measurements, quantum systems evolve along stochastic quantum trajectories that can be naturally equipped with a geometric phase observable via a post-selection in a final projective measurement. When post-selecting the trajectories to form a close loop, the geometric phase undergoes a topological transition driven by the measurement strength. Here, we study the geometric phase of a subset of self-closing trajectories induced by a continuous Gaussian measurement of a single qubit system. We utilize a stochastic path integral that enables the analysis of rare self-closing events using action methods and develop the formalism to incorporate the measurement-induced geometric phase therein. We show that the geometric phase of the most likely trajectories undergoes a topological transition for self-closing trajectories as a function of the measurement strength parameter. Moreover, the inclusion of Gaussian corrections in the vicinity of the most probable self-closing trajectory quantitatively changes the transition point in agreement with results from numerical simulations of the full set of quantum trajectories.

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Section: Introductionmentioning

confidence: 99%

Action formalism for geometric phases from self-closing quantum trajectories

Shea,

Romito

2024

J. Phys. A: Math. Theor.

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Eluding Zeno effect via dephasing and detuning

Cuadrado,

Luis

2024

Phys. Scr.

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We analyze some variants of the Zeno effect in which the frequent observation of the population of an intermediate state does not prevent the transition of the system from the initial state to a certain final state. This is achieved by considering system observation involving suitably introduced phase shifts and detunings that leads to a rather rich measurement-induced dynamics by the alteration of the interference governing quantum evolution. For initial nonclassical states this includes entanglement as a way of evolution from the initial to the final state avoiding the intermediate state. This possibility is presented in a particular physical scenario in the form of a chain of three coupled harmonic oscillators, but we readily show then that the idea can be applied to other physical systems as well, such as atomic-level dynamics. These results are significant for a better knowledge of fundamental quantum concepts as well as regarding suitable applications in the proper control of quantum dynamics, as this is a key feature of modern applications of the quantum theory.

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