Quantum persistence: A random-walk scenario

Goswami, Sanchari; Sen, Parongama; Das, Arnab

doi:10.1103/physreve.81.021121

Cited by 12 publications

(24 citation statements)

References 16 publications

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“…The quantum renewal equation (17) and the Z transforms Eqs. (36,37) give a rather general relation between the amplitude of first detection φ n and the wave function of the system free of measurement |ψ f . In that sense the problem of first detection reduces to the solution of the Schrödinger equation, e.g.…”

Section: Discussionmentioning

confidence: 99%

“…The recent advance of single particle quantum tracking and measurement, for systems where coherence is maintained for relatively long times, is clearly a reason to be optimistic with respect to possible first detection measurements. Such measurements could test our predictions as well as those of a variety of other theoretical approaches [14,23,[31][32][33][34][35][36][37][38], some of which are compared with our results towards the end of this manuscript.…”

Section: Introductionmentioning

confidence: 86%

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Quantum walks: The first detected passage time problem

2017

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Even after decades of research, the problem of first passage time statistics for quantum dynamics remains a challenging topic of fundamental and practical importance. Using a projective measurement approach, with a sampling time τ, we obtain the statistics of first detection events for quantum dynamics on a lattice, with the detector located at the origin. A quantum renewal equation for a first detection wave function, in terms of which the first detection probability can be calculated, is derived. This formula gives the relation between first detection statistics and the solution of the corresponding Schrödinger equation in the absence of measurement. We illustrate our results with tight-binding quantum walk models. We examine a closed system, i.e., a ring, and reveal the intricate influence of the sampling time τ on the statistics of detection, discussing the quantum Zeno effect, half dark states, revivals, and optimal detection. The initial condition modifies the statistics of a quantum walk on a finite ring in surprising ways. In some cases, the average detection time is independent of the sampling time while in others the average exhibits multiple divergences as the sampling time is modified. For an unbounded one-dimensional quantum walk, the probability of first detection decays like (time)^{(-3)} with superimposed oscillations, with exceptional behavior when the sampling period τ times the tunneling rate γ is a multiple of π/2. The amplitude of the power-law decay is suppressed as τ→0 due to the Zeno effect. Our work, an extended version of our previously published paper, predicts rich physical behaviors compared with classical Brownian motion, for which the first passage probability density decays monotonically like (time)^{-3/2}, as elucidated by Schrödinger in 1915.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 86%

Quantum walks: The first detected passage time problem

2017

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“…But for CCM, the direction reversal probability f is greater than 1/2 for all λ < 1 and f → 1/2 for λ → 1. Through further analysis of time correlation and other relevant quantities it was shown that direction reversal is preferred in these cases [51]. In the equivalent picture of the walk in the abstract space for gains and losses, it is similar to the fact that here individuals has a tendency to make a gain immediately after a loss and vice versa.…”

Section: Antipersistence Effect In Cc/ccm Walkmentioning

confidence: 80%

“…It was also shown in [51] that the "antipersistence effect" is maximum for no saving and decreases with saving. This is perhaps in tune with the human feeling of security associated with the saving factor.…”

Section: Antipersistence Effect In Cc/ccm Walkmentioning

confidence: 99%

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Kinetic Exchange Models in Economics and Sociology

Goswami

Chakraborti

2015

Springer Proceedings in Mathematics &Amp; Statistics

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In this article, we briefly review the different aspects and applications of kinetic exchange models in economics and sociology. Our main aim is to show in what manner the kinetic exchange models for closed economic systems were inspired by the kinetic theory of gas molecules. The simple yet powerful framework of kinetic theory, first proposed in 1738, led to the successful development of statistical physics of gases towards the end of the 19th century. This framework was successfully adapted to modeling of wealth distributions in the early 2000's. In later times, it was applied to other areas like firm dynamics and opinion formation in the society, as well. We have tried to present the flavour of the several models proposed and their applications, intentionally leaving out the intricate mathematical and technical details.

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