Symmetric exclusion process under stochastic resetting

Basu, Urna; Kundu, Anupam; Pal, A.

doi:10.1103/physreve.100.032136

Cited by 97 publications

(112 citation statements)

References 57 publications

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“…The hopping process can be mapped to a set of independent random walkers on a fully connected, large set of states. Recent developments on stochastic resetting of interacting particle systems have addressed properties of the symmetric exclusion process [36] and totally asymmetric exclusion process [42], and in [43], the phase diagram in the plane of temperature and resetting rate has been presented for the Ising model, an interacting system with a thermodynamic phase transition in its equilibrium state. However, the present model allows for a mapping of the model of growing networks, as well as to a microscopic version of Kingman's house-of-cards model.…”

Section: Discussionmentioning

confidence: 99%

Non-conserving zero-range processes with extensive rates under resetting

Grange

2020

J. Phys. Commun.

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We consider a non-conserving zero-range process with hopping rate proportional to the number of particles at each site. Particles are added to the system with a site-dependent creation rate, and vanish with a uniform annihilation rate. On a fully-connected lattice with a large number of sites, the meanfield geometry leads to a negative binomial law for the number of particles at each site, with parameters depending on the hopping, creation and annihilation rates. This model can be mapped to population dynamics (if the creation rates are reproductive fitnesses in a haploid population, and the hopping rate is the mutation rate). It can also be mapped to a Bianconi-Barabási model of a growing network with random rewiring of links (if creation rates are the rates of acquisition of links by nodes, and the hopping rate is the rewiring rate). The steady state has recently been worked out and gives rise to occupation numbers that reproduce Kingman's house-of-cards model of selection and mutation. In this paper we solve the master equation using a functional method, which yields integral equations satisfied by the occupation numbers. The occupation numbers are shown to forget initial conditions at an exponential rate that decreases linearly with the fitness level. Moreover, they can be computed exactly in the Laplace domain, which allows to obtain the steady state of the system under resetting. The result modifies the house-of-cards result by simply adding a skewed version of the initial conditions, and by adding the resetting rate to the hopping rate.

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Section: Discussionmentioning

confidence: 99%

Non-conserving zero-range processes with extensive rates under resetting

Grange

2020

J. Phys. Commun.

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“…(23) from the result in Eq. (21). An exact, real-time, formula can also be given for the probability to be in the return phase p R (t); and hence for the probability p D (t) = 1 − p R (t) to be in the diffusive phase.…”

Section: Transient and Steady-state Solutionsmentioning

confidence: 99%

“…The simple model of diffusion with stochastic resetting has been extended and generalized to cover: diffusion in the presence of a potential [6][7][8], in a domain [9][10][11][12], and arbitrary dimensions [13]; diffusion in the presence of non-exponential resetting time distributions e.g., deterministic [14], intermittent [4], non-Markovian [15], non-stationary [16], with general time dependent resetting rates [17], as well as other protocols [18]; and diffusion in the presence of interactions [19][20][21]. The effect of resetting on random walks [22,23], continuous time random walks [24][25][26], Lévy flights [27,28], and other forms of stochastic motion [29][30][31][32][33], has also been studied.…”

Section: Introductionmentioning

confidence: 99%

Time-dependent density of diffusion with stochastic resetting is invariant to return speed

2019

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The canonical Evans-Majumdar model for diffusion with stochastic resetting to the origin assumes that resetting takes zero time: upon resetting the diffusing particle is teleported back to the origin to start its motion anew. However, in reality getting from one place to another takes a finite amount of time which must be accounted for as diffusion with resetting already serves as a model for a myriad of processes in physics and beyond. Here we consider a situation where upon resetting the diffusing particle returns to the origin at a finite (rather than infinite) speed. This creates a coupling between the particle's random position at the moment of resetting and its return time, and further gives rise to a non-trivial cross-talk between two separate phases of motion: the diffusive phase and the return phase. We show that each of these phases relaxes to the stead-state in a unique manner; and while this could have also rendered the total relaxation dynamics extremely non-trivial our analysis surprisingly reveals otherwise. Indeed, the time-dependent distribution describing the particle's position in our model is completely invariant to the speed of return. Thus, whether returns are slow or fast, we always recover the result originally obtained for diffusion with instantaneous returns to the origin.

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“…Noteworthy in this regard is the Evans-Majumdar model for diffusion with stochastic resetting [2,3]. This model has led to a large volume of work covering diffusion with resetting in the presence of a potential field [5,37,38], in different geometrical confinements [39][40][41][42], in higher dimensions [43], with non-Poissonian resetting protocols [44][45][46][47][48], with interactions [49][50][51], and more. The model was further extended to study other, i.e.…”

Section: Introductionmentioning

confidence: 99%

Invariants of motion with stochastic resetting and space-time coupled returns

2019

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Motion under stochastic resetting serves to model a myriad of processes in physics and beyond, but in most cases studied to date resetting to the origin was assumed to take zero time or a time decoupled from the spatial position at the resetting moment. However, in our world, getting from one place to another always takes time and places that are further away take more time to be reached. We thus set off to extend the theory of stochastic resetting such that it would account for this inherent spatio-temporal coupling. We consider a particle that starts at the origin and follows a certain law of stochastic motion until it is interrupted at some random time. The particle then returns to the origin via a prescribed protocol. We study this model and surprisingly discover that the shape of the steady-state distribution which governs the stochastic motion phase does not depend on the return protocol. This shape invariance then gives rise to a simple, and generic, recipe for the computation of the full steady state distribution. Several case studies are analyzed and a class of processes whose steady state is completely invariant with respect to the speed of return is highlighted. For processes in this class we recover the same steady-state obtained for resetting with instantaneous returns-irrespective of whether the actual return speed is high or low. Our work significantly extends previous results on motion with stochastic resetting and is expected to find various applications in statistical, chemical, and biological physics.

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Symmetric exclusion process under stochastic resetting

Cited by 97 publications

References 57 publications

Non-conserving zero-range processes with extensive rates under resetting

Non-conserving zero-range processes with extensive rates under resetting

Time-dependent density of diffusion with stochastic resetting is invariant to return speed

Invariants of motion with stochastic resetting and space-time coupled returns

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