A series of frequent measurements on a quantum system (Zeno-like measurements) is shown to result in the "purification" of another quantum system in interaction with the former. Even though the measurements are performed on the former system, their effect drives the latter into a pure state, irrespectively of its initial (mixed) state, provided certain conditions are satisfied.PACS numbers: 03.65.XpIt is well known that unstable particles or quantum states display a peculiar behavior at short and long times [1]. Phenomenologically, they are known to decay exponentially and this is well confirmed experimentally [2]. Short-time deviations were only observed very recently [3]. The deviations from the familiar exponential decay law are unavoidable consequences of the quantum dynamics both at short and long times, and the derivation of the exponential decay law itself is not a trivial matter in quantum mechanics. These deviations reflect the unitarity of the time evolution operator or the time reversal symmetry of the Schrödinger equation at short times and the lower boundedness of the Hamiltonian or the stability of the vacuum at long times. See, e.g., Ref.[1] for a review.The quantum behavior of unstable states at short times has been one of the central issues of investigation and discussion in recent years, since it is closely connected to the so-called quantum Zeno effect (QZE) [4,5], where the act of measurement [6] (usually represented by the von Neumann projection or the generalized spectral decomposition [7]) affects in an essential way the dynamics of the measured system and results in a hindrance of the decay process. The first attempt at the experimental observation of the QZE in an atomic transition process [8], following Cook's theoretical work [9], has triggered heated discussions on this subject. Furthermore, another exciting experiment has been reported very recently: the observation of the QZE (and also of the inverse QZE [10]) in an atomic tunneling process [11], which is the first experimental observation of the (inverse) QZE in a truly unstable quantum system, unlike in the previous experiment [8] performed on an oscillating system.In this Letter, we will shed new light on another (and so far not well explored) feature of the quantum dynamics with measurements, closely related to the QZE. Notice first that the system under consideration cannot be considered completely isolated and usually interacts with other systems. Therefore, it would be interesting and maybe more realistic to consider the case where the measurement, represented by a von Neumann projection for simplicity, is not performed on the total system, but only on the system of interest. Here, we consider such measurements and address the following point: How does a series of frequent measurements on a system affect the dynamics of another system in interaction with the former? Under frequent measurements performed only on the former system, the latter evolves away from its initial state. We shall show that such measurements can result i...
We present a novel procedure to purify quantum states, i.e., purification through Zeno-like measurements. By simply repeating one and the same measurement on a quantum system, one can purify another system in interaction with the former. The conditions for the (efficient) purification are specified on a rather general setting, and the framework of the method possesses wide applicability. It is explicitly demonstrated on a specific setup that the purification becomes very efficient by tuning relevant parameters.KEYWORDS: purification of quantum states, quantum Zeno effect, repeated measurement One cannot observe a quantum system without any disturbance on the object, and the dynamics of the quantum system is affected by the measurement. An interesting manifestation of this effect is the "quantum Zeno effect" (QZE):1-3) if one repeats measurement very frequently in order to ascertain whether a system remains in the initial state, the evolution of the system is slowed down and totally hindered in the limit of infinite frequency. Or conversely, one can also accelerate the decay of an unstable state by repeating the measurement less frequently than a critical frequency (inverse QZE). 4)These are typical examples of the effects of measurement on quantum dynamics.In this article, we present another interesting effect of measurement on quantum dynamics when the measurement is repeated as in the case of the (inverse) QZE: purification of quantum state through Zeno-like measurements.5) We show in the following that a series of measurements on a quantum system indirectly affects the dynamics of another system in interaction with the former, and the latter (initially in any mixed state) is driven into a pure state, provided certain conditions are satisfied. The state of the latter system is purified through the repeated measurement on the former.In the ideas of quantum information and computation, quantum coherence plays crucial roles.6, 7) It is hence one of the important issues to be addressed how to maintain and/or recover quantum coherence, and various schemes have been proposed attacking this subject. 6-14)The work presented here contributes to this issue and provides a novel method to purify quantum states (i.e., to recover quantum coherence), which is simple compared to the standard purification techniques 6, 9, 10) and the framework is rather general.Let a total system A+B be described by a Hamiltonian of the formwhere H A(B) is a free Hamiltonian of system A(B) and H int is an interaction between A and B. We prepare system A in a pure state |φ at time t = 0, while the initial state of system B, denoted by ρ B , can be arbitrary * E-mail address: yuasa@hep.phys.waseda.ac.jp † E-mail address: hiromici@waseda.jp (a mixed state). The total system starts to evolve from the initial statewith the Hamiltonian (1), and we check the state of system A at time t = τ . If it is confirmed that system A remains in its initial state |φ , the state of the total system is projected by a projection operatorand restarts to evolve. We ...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
