Macroscopic Transport Equations in Many-Body Systems from Microscopic Exclusion Processes in Disordered Media: A Review

Galanti, Marta; Fanelli, Duccio; Piazza, Francesco

doi:10.3389/fphy.2016.00033

Cited by 9 publications

(5 citation statements)

References 82 publications

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“…A simple model for the reduction of rotational diffusion in highly concentrated protein solutions was given by Koenig and Brown in . All in all, the extent of interparticle interactions in highly non‐ideal systems may be not trivial to determine: the effect of high concentration on the translational and rotational diffusion of proteins or “the effect of proteins on protein diffusion” is an active field of research , as it is strictly related to the effect of biomolecular crowding in in‐cell studies .…”

Section: Discussionmentioning

confidence: 99%

The bigger they are, the harder they fall: A topical review on sedimented solutes for solid‐state NMR

Ravera

2014

Concepts Magnetic Resonance

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Sample preparation for solid-state NMR of soluble proteins is all but a trivial accomplishment and often represents the factor that determines the success of the experiments, despite the dramatic methodological and technological improvements in the field of SSNMR. Several different sample preparation have been proposed and applied over the years, with varied results. Among those methods we have proposed the use of sedimentation for obtaining samples with high sensitivity and resolution. This review aims at covering the applications of NMR to sedimented solutes from its first description to the latest developments with implications in the field of DNP.

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Section: Discussionmentioning

confidence: 99%

The bigger they are, the harder they fall: A topical review on sedimented solutes for solid‐state NMR

Ravera

2014

Concepts Magnetic Resonance

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“…This is an interesting topic for further investigation. Finally, from the biological viewpoint, it is of course of interest to explore the consequences of allowing turning frequencies to depend on density distributions in order to incorporate more complex spatial and temporal dependencies of microscopic quantities into models of related phenomena, such as macromolecular crowding [16], aggregation [41], or microscopic exclusion processes of intracellular transport [20], just to mention a few.…”

Section: Discussionmentioning

confidence: 99%

Derivation of a bacterial nutrient-taxis system with doubly degenerate cross-diffusion as the parabolic limit of a velocity-jump process

Plaza

2019

J. Math. Biol.

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This paper is devoted to the justification of the macroscopic, mean-field nutrient taxis system with doubly degenerate cross-diffusion proposed by Leyva et al. [39] to model the complex spatio-temporal dynamics exhibited by the bacterium B. subtilis during experiments run in vitro. This justification is based on a microscopic description of the movement of individual cells whose changes in velocity (in both speed and orientation) obey a velocity jump process [47], governed by a transport equation of Boltzmann type. For that purpose, the asymptotic method introduced by Hillen and Othmer [27,48] is applied, which consists of the computation of the leading order term in a regular Hilbert expansion for the solution to the transport equation, under an appropriate parabolic scaling and a first order perturbation of the turning rate of Schnitzer type [54]. The resulting parabolic limit equation at leading order for the bacterial cell density recovers the degenerate nonlinear cross diffusion term and the associated chemotactic drift appearing in the original system of equations. Although the bacterium B. subtilis is used as a prototype, the method and results apply in more generality.2010 Mathematics Subject Classification. 35K65, 92C17, 60J75.

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“…Essentially, two populations of particles, mimicking pedestrians walking in a built environment, en- 1 A simple exclusion process refers to the stochastic motion of interacting particles on a lattice where the interaction is given by the exclusion (excluded "volume" constraints) property, i.e., two particles may not occupy the same site simultaneously. We refer the reader to [7] for rigorous considerations on the simple exclusion model and its hydrodynamic limits and to [8] for a basic modeling perspective.…”

Section: Introductionmentioning

confidence: 99%

When diffusion faces drift: consequences of exclusion processes for bi--directional pedestrian flows

Cirillo,

Colangeli,

Muntean

et al. 2020

Preprint

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Stochastic particle-based models are useful tools for describing the collective movement of large crowds of pedestrians in crowded confined environments.Using descriptions based on the simple exclusion process, two populations of particles, mimicking pedestrians walking in a built environment, enter a room from two opposite sides. One population is passive -being unaware of the local environment; particles belonging to this group perform a symmetric random walk. The other population has information on the local geometry in the sense that as soon as particles enter a visibility zone, a drift activates them. Their self-propulsion leads them towards the exit. This second type of species is referred here as active. The assumed crowdedness corresponds to a near-jammed scenario. The main question we ask in this paper is: Can we induce modifications of the dynamics of the active particles to improve the outgoing current of the passive particles? To address this question, we compute occupation number profiles and currents for both populations in selected parameter ranges. Besides observing the more classical faster-is-slower effect, new features appear $ Fully documented templates are available in the elsarticle package on CTAN.

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Macroscopic Transport Equations in Many-Body Systems from Microscopic Exclusion Processes in Disordered Media: A Review

Cited by 9 publications

References 82 publications

The bigger they are, the harder they fall: A topical review on sedimented solutes for solid‐state NMR

The bigger they are, the harder they fall: A topical review on sedimented solutes for solid‐state NMR

Derivation of a bacterial nutrient-taxis system with doubly degenerate cross-diffusion as the parabolic limit of a velocity-jump process

When diffusion faces drift: consequences of exclusion processes for bi--directional pedestrian flows

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