Quantum walks: The first detected passage time problem

Friedman, H.; Kessler, David A.; Barkai, Eli

doi:10.1103/physreve.95.032141

Cited by 77 publications

(199 citation statements)

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“…3. When ξ = 0, then re iβ = 1 and we recover the known result [5,21,22]. In the limit of large ξ or small τ we find a remarkably simple relation to the incidence time:…”

supporting

confidence: 82%

“…Given a graph, and an Hamiltonian H, the presence or absence of a particle starting on node |x i is recorded at a node |x d sampled with period τ . H, τ and the measurement process [23], define the problem, which differs markedly from the corresponding wellstudied classical first-passage-time problem [24][25][26][27][28].Recently, a quantum renewal equation which relates the statistics of first detection times to the quantum evolution operator of the measurement-free system was derived [21,22]. This equation was used investigate the statistics of the first detected return, i.e.…”

mentioning

confidence: 99%

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First Detected Arrival of a Quantum Walker on an Infinite Line

2018

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The first detection of a quantum particle on a graph has been shown to depend sensitively on the distance ξ between detector and initial location of the particle, and on the sampling time τ . Here we use the recently introduced quantum renewal equation to investigate the statistics of first detection on an infinite line, using a tight-binding lattice Hamiltonian with nearest-neighbor hops. Universal features of the first detection probability are uncovered and simple limiting cases are analyzed. These include the large ξ limit, the small τ limit and the power law decay with attempt number of the detection probability over which quantum oscillations are superimposed. For large ξ the first detection probability assumes a scaling form and when the sampling time is equal to the inverse of the energy band width, non-analytical behaviors arise, accompanied by a transition in the statistics. The maximum total detection probability is found to occur for τ close to this transition point. When the initial location of the particle is far from the detection node we find that the total detection probability attains a finite value which is distance independent.Introduction: Recent experimental advances have made it possible to measure quantum walks at the single particle level [1][2][3][4]. A related advance is the quantum first detection problem which has drawn considerable theoretical attention [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22], as it deals with the basic issue of when the particle will first be detected in a target state. Originally the topic emerged in the context of quantum search algorithms. Given a graph, and an Hamiltonian H, the presence or absence of a particle starting on node |x i is recorded at a node |x d sampled with period τ . H, τ and the measurement process [23], define the problem, which differs markedly from the corresponding wellstudied classical first-passage-time problem [24][25][26][27][28].Recently, a quantum renewal equation which relates the statistics of first detection times to the quantum evolution operator of the measurement-free system was derived [21,22]. This equation was used investigate the statistics of the first detected return, i.e. when |x i = |x d . The present Letter focuses on the first detected arrival, |x i = |x d . The questions to be tackled are: Given τ and the tight-binding Hamiltonian on an infinite line, what are the basic properties of the first detection probability? More specifically: Will the particle always be detected? If not, then what is the optimal sampling rate for which the total detection probability is maximized? The existence of an optimum is expected, since the Zeno effect [29,30] suppresses detection for too frequent measurements, while a too large τ aids the escape from the detector. What is the general behavior of the detection probability at attempt number n, which we denote F n ? What is its asymptotics for small and large n and how does it depend on the initial distance ξ = |x d − x i | of the particle from the detector? ...

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“…3. When ξ = 0, then re iβ = 1 and we recover the known result [5,21,22]. In the limit of large ξ or small τ we find a remarkably simple relation to the incidence time:…”

supporting

confidence: 82%

mentioning

confidence: 99%

First Detected Arrival of a Quantum Walker on an Infinite Line

2018

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“…For example, the spectral properties of quantum systems subjected to resetting have been studied in [166]. Another quantum setup where resetting can play an important role is the quantum random walk subjected to perturbations caused by repeated measurements [167][168][169][170].…”

Section: Quantum Dynamics With Resetmentioning

confidence: 99%

Stochastic resetting and applications

Evans

Majumdar

Schehr

2020

J. Phys. A: Math. Theor.

503

600

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In this Topical Review we consider stochastic processes under resetting, which have attracted a lot of attention in recent years. We begin with the simple example of a diffusive particle whose position is reset randomly in time with a constant rate r, which corresponds to Poissonian resetting, to some fixed point (e.g. its initial position). This simple system already exhibits the main features of interest induced by resetting: (i) the system reaches a nontrivial nonequilibrium stationary state (ii) the mean time for the particle to reach a target is finite and has a minimum, optimal, value as a function of the resetting rate r. We then generalise to an arbitrary stochastic process (e.g. Lévy flights or fractional Brownian motion) and non-Poissonian resetting (e.g. power-law waiting time distribution for intervals between resetting events). We go on to discuss multiparticle systems as well as extended systems, such as fluctuating interfaces, under resetting. We also consider resetting with memory which implies resetting the process to some randomly selected previous time. Finally we give an overview of recent developments and applications in the field.

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“…A well investigated approach is to consider measurements on the original node, repeated stroboscopically until the first detection. The problem is to find the distribution of the number of attempts n till first detection [5][6][7][8][9][10][11][12][13][14][15][16][17][18]. This sheds light on the backfire of measurement on unitary evolution, and on time processes in quantum mechanics.…”

Section: Introductionmentioning

confidence: 99%

“…The goal of this paper is to investigate the fluctuations of the number of measurements needed till the first return is recorded, namely the variance of n. It was shown previously that these can be very large close to critical sampling parameters even for small systems [1,13]. Here we provide formulas for the blow-ups of the fluctuations, using an elegant mapping of the quantum problem to 18 Measurements M are performed every τ units of time, between which the system evolves unitarily withÛ (τ ).…”

Section: Introductionmentioning

confidence: 99%

Large fluctuations of the first detected quantum return time

Yin

Ziegler

Thiel

et al. 2019

Phys. Rev. Research

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How long does it take a quantum particle to return to its origin? As shown previously under repeated projective measurements aimed to detect the return, the closed cycle yields a geometrical phase which shows that the average first detected return time is quantized. For critical sampling times or when parameters of the Hamiltonian are tuned this winding number is modified. These discontinuous transitions exhibit gigantic fluctuations of the return time. While the general formalism of this problem was studied at length, the magnitude of the fluctuations, which is quantitatively essential, remains poorly characterized. Here, we derive explicit expressions for the variance of the return time, for quantum walks in finite Hilbert space. A classification scheme of the diverging variance is presented, for four different physical effects: the Zeno regime, when the overlap of an energy eigenstate and the detected state is small and when two or three phases of the problem merge. These scenarios present distinct physical effects which can be analyzed with the fluctuations of return times investigated here, leading to a topology-dependent time-energy uncertainty principle.

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Quantum walks: The first detected passage time problem

Cited by 77 publications

References 50 publications

First Detected Arrival of a Quantum Walker on an Infinite Line

First Detected Arrival of a Quantum Walker on an Infinite Line

Stochastic resetting and applications

Large fluctuations of the first detected quantum return time

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