Anomalous diffusion and ergodicity breaking in heterogeneous diffusion processes

Cherstvy, Andrey G.; Chechkin, Aleksei V.; Metzler, Ralf

doi:10.1088/1367-2630/15/8/083039

Cited by 293 publications

(447 citation statements)

References 70 publications

(61 reference statements)

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“…1a,b. HDPs are weakly non-ergodic and ageing, that is, their dynamics depends explicitly on the time gap between original initiation of the system and start of the measurement [32][33][34][35][36]. We note that the ageing properties of HDPs [35] embodied in the ensemble and time averaged MSDs are in fact similar to those of subdiffusive continuous time random walks [37] and scaled Brownian motion [38].…”

Section: Introductionmentioning

confidence: 80%

“…For reference in what follows we also mention that the probability density function of HDPs obeys has the exponential form [33] …”

Section: Observablesmentioning

confidence: 99%

“…(2) is [D 0 ] = cm 2−α0 sec −1 . The exponent (3) designates subdiffusion for α 0 < 0 and superdiffusion for 0 < α 0 [32][33][34][35][36]. The profiles of the diffusivity for these cases are shown in Fig.…”

Section: Introductionmentioning

confidence: 99%

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Ergodicity breaking and particle spreading in noisy heterogeneous diffusion processes

Cherstvy

Metzler

2015

The Journal of Chemical Physics

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We study noisy heterogeneous diffusion processes with a position dependent diffusivity of the form D(x) ∼ D0|x| α in the presence of annealed and quenched disorder of the environment, corresponding to an effective variation of the exponent α in time and space. In the case of annealed disorder, for which effectively α = α(t) we show how the long time scaling of the ensemble mean squared displacement (MSD) and the amplitude variation of individual realizations of the time averaged MSD are affected by the disorder strength. For the case of quenched disorder, the long time behavior becomes effectively Brownian after a number of jumps between the domains of a stratified medium. In the latter situation the averages are taken over both an ensemble of particles and different realizations of the disorder. As physical observables we analyze in detail the ensemble and time averaged MSDs, the ergodicity breaking parameter, and higher order moments of the time averages.

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Section: Introductionmentioning

confidence: 80%

“…For reference in what follows we also mention that the probability density function of HDPs obeys has the exponential form [33] …”

Section: Observablesmentioning

confidence: 99%

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Ergodicity breaking and particle spreading in noisy heterogeneous diffusion processes

Cherstvy

Metzler

2015

The Journal of Chemical Physics

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“…In some literature, the squared RSD is utilized as the ergodicity breaking parameter [14,[18][19][20].) The RF and RSD analyses for the TAMSD are useful if the systems are non-ergodic.…”

Section: Introductionmentioning

confidence: 99%

Fluctuation analysis of time-averaged mean-square displacement for the Langevin equation with time-dependent and fluctuating diffusivity

2015

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The mean-square displacement (MSD) is widely utilized to study the dynamical properties of stochastic processes. The time-averaged MSD (TAMSD) provides some information on the dynamics which cannot be extracted from the ensemble-averaged MSD. In particular, the relative standard deviation (RSD) of the TAMSD can be utilized to study the long time relaxation behavior. In this work, we consider a class of Langevin equations which are multiplicatively coupled to timedependent and fluctuating diffusivities. Various interesting dynamics models such as entangled polymers and supercooled liquids can be interpreted as the Langevin equations with time-dependent and fluctuating diffusivities. We derive a general formula for the RSD of the TAMSD for the Langevin equation with the time-dependent and fluctuating diffusivity. We show that the RSD can be expressed in terms of the correlation function of the diffusivity. The RSD exhibits the crossover at the long time region. The crossover time is related to a weighted average relaxation time for the diffusivity. Thus the crossover time gives some information on the relaxation time of fluctuating diffusivity which cannot be extracted from the ensemble-averaged MSD. We discuss the universality and possible applications of the formula via some simple examples.

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“…The position dependence of diffusivity can also significantly influence properties of the dispersion, such as viscosity and the mixing facility of multicomponent systems. In fact, inhomogeneity can lead to fundamentally new behavior such as anomalous diffusion (super-or subdiffusion), nonergodic effects, 13,14 and the occurrence of multiplicative noise. 15 Therefore, when describing the system dynamics and explaining related experimental results, it is important to consider any diffusion inhomogeneity effects and their potential interplay with any imposed flow profiles, as this will affect the spatial distribution of the particles along the channel with time and hence the flux of particles.…”

Section: Introductionmentioning

confidence: 99%

Spatially dependent diffusion coefficient as a model for pH sensitive microgel particles in microchannels

2016

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Solute transport and intermixing in microfluidic devices is strongly dependent on diffusional processes. Brownian Dynamics simulations of pressure-driven flow of model microgel particles in microchannels have been carried out to explore these processes and the factors that influence them. The effects of a pH-field that induces a spatial dependence of particle size and consequently the self-diffusion coefficient and system thermodynamic state were focused on. Simulations were carried out in 1D to represent some of the cross flow dependencies, and in 2D and 3D to include the effects of flow and particle concentration, with typical stripe-like diffusion coefficient spatial variations. In 1D, the mean square displacement and particle displacement probability distribution function agreed well with an analytically solvable model consisting of infinitely repulsive walls and a discontinuous pHprofile in the middle of the channel. Skew category Brownian motion and nonGaussian dynamics were observed, which follows from correlations of step lengths in the system, and can be considered to be an example of so-called "diffusing diffusivity." In Poiseuille flow simulations, the particles accumulated in regions of larger diffusivity and the largest particle concentration throughput was found when this region was in the middle of the channel. The trends in the calculated cross-channel diffusional behavior were found to be very similar in 2D and 3D. Published by AIP Publishing. [http://dx

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Anomalous diffusion and ergodicity breaking in heterogeneous diffusion processes

Cited by 293 publications

References 70 publications

Ergodicity breaking and particle spreading in noisy heterogeneous diffusion processes

Ergodicity breaking and particle spreading in noisy heterogeneous diffusion processes

Fluctuation analysis of time-averaged mean-square displacement for the Langevin equation with time-dependent and fluctuating diffusivity

Spatially dependent diffusion coefficient as a model for pH sensitive microgel particles in microchannels

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