Theory and Experiments for Disordered Elastic Manifolds, Depinning, Avalanches, and Sandpiles

Wiese, Kay Joerg

doi:10.48550/arxiv.2102.01215

Cited by 14 publications

(63 citation statements)

References 611 publications

(1,139 reference statements)

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“…Then, from Eqs. (11,12), one finds that R ∞ (x) = 0 and P ∞ (x) = 1/ < x > ∞ x g(x )dx . After some lengthy algebra, the disconnected susceptibility in the stationary state can be simply expressed as…”

Section: Susceptibilities In the Mean-field Epmmentioning

confidence: 99%

“…[19], together with its solution for an exponential distribution of random jumps g(x). For a general distribution g(x) it can be recast as P y (x) = P 0 (x + y) + g(x)F 0 (y) + y 0 dy F 0 (y )R y−y (x), (11) with F 0 (x) =…”

mentioning

confidence: 99%

“…where P y (x) is given by Eqs. (11,12). (The notation m anticipates on the analogy with the magnetization in the RFIM.)…”

mentioning

confidence: 99%

“…The loading curve, i.e., the average stress versus applied strain σ(γ), is then obtained by combining Eqs. ( 14), ( 16), (11) and (12) 1: Average stress σ versus applied strain γ for the mean-field EPM with a distribution of random jumps chosen as an exponential and that of the initial local stress (or stability) distribution as a linear combination of two exponentials 19 . As the strength ∆0 of the disorder increases (for fixed parameters of the random jump distribution), one passes from a regime with a discontinuous stress jump to a continuous behavior with a stress overshoot to finally a monotonically increasing regime.…”

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confidence: 99%

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Emergence of a random field at the yielding transition of a mean-field Elasto-Plastic model

Rossi,

Tarjus

2022

Preprint

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We study the mean-field limit of an elasto-plastic model introduced to describe the yielding transition of athermally and quasi-statically sheared amorphous solids. We focus on the sample-tosample fluctuations, which we characterize analytically, and investigate in detail the analogy with the athermally driven random-field Ising model. We stress that the random field at the yielding transition is an emerging disorder and we investigate the various factors that determine its strength.

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Section: Susceptibilities In the Mean-field Epmmentioning

confidence: 99%

mentioning

confidence: 99%

“…where P y (x) is given by Eqs. (11,12). (The notation m anticipates on the analogy with the magnetization in the RFIM.)…”

mentioning

confidence: 99%

mentioning

confidence: 99%

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Emergence of a random field at the yielding transition of a mean-field Elasto-Plastic model

Rossi,

Tarjus

2022

Preprint

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“…A successful theoretical tool to study interfaces is provided by the disordered elastic systems framework [18][19][20][21][22][23]: interfaces are modeled as elastic objects evolving in a quenched disordered landscape and subject to thermal noise. Remarkably, this minimal description is enough to account for many key statistical features of the geometry and dynamics of both static or driven interfaces [24].…”

mentioning

confidence: 99%

Microscopic interplay of temperature and disorder of a one-dimensional elastic interface

Caballero,

Giamarchi,

Lecomte

et al. 2021

Preprint

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Universal excursion and bridge shapes in ABBM/CIR/Bessel processes

Baldassarri¹

2021

J. Stat. Mech.

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Several years ago, in the context of the physics of hysteresis in magnetic materials, a simple stochastic model has been introduced: the ABBM model. Later, the ABBM model has been advocated as a paradigm for the description of a broad class of diverse phenomena, baptized ‘crackling noise phenomena’. The model reproduces many statistical features of such intermittent signals, as for instance the statistics of burst (or avalanche) durations and sizes, in particular the power law exponents that would characterize the dynamics as critical. In order to go beyond such ‘critical exponents’, the measure of the average shape of the avalanche has also been proposed. Here, the exact calculation of the average (as well as the fluctuations) of the avalanche shape for the ABBM model is presented, showing that its normalised shape does not depend on the external drive. Moreover, the average (and the fluctuations) of the multi-avalanche shape, that is the average shape of a sequence of avalanches of fixed total duration, is also computed. Surprisingly, the two quantities (avalanche and multi-avalanche normalised shapes) are exactly the same. This result is obtained using the exact solution of the ABBM model, which is obtained leveraging the equivalence with the Cox–Ingersoll–Ross process (CIR), rigorously obtained with a so called ‘time change’. A simple presentation of this and other known relevant exact results is provided: notably the correspondence of the ABBM/CIR model with the Rayleigh model and, more importantly, with the generalised Bessel process, which describes the dynamics of the modulus of the multi dimensional Ornstein–Uhlenbeck process (exactly as the Bessel process does for the Brownian process). As a consequence, our main finding, that is the correspondence between the excursion (avalanche) and bridge (multi-avalanche) shape distributions, turns to apply to all the aforementioned stochastic processes. In simple words: if we consider the distance from the origin of such diffusive particles, the (normalised) average shape of its trajectory (and the fluctuations around that) until a return in a time T is the same, whether it has returned before T or not.

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Theory and Experiments for Disordered Elastic Manifolds, Depinning, Avalanches, and Sandpiles

Cited by 14 publications

References 611 publications

Emergence of a random field at the yielding transition of a mean-field Elasto-Plastic model

Emergence of a random field at the yielding transition of a mean-field Elasto-Plastic model

Microscopic interplay of temperature and disorder of a one-dimensional elastic interface

Universal excursion and bridge shapes in ABBM/CIR/Bessel processes

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