Your search keyword '"Sorkin, Benjamin"' showing total 16 results

1. Second Law of Thermodynamics without Einstein Relation

Author

Sorkin, Benjamin, Diamant, Haim, Ariel, Gil, and Markovich, Tomer

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Soft Condensed Matter

Abstract

Materials that are constantly driven out of thermodynamic equilibrium, such as active and living systems, typically violate the Einstein relation. This may arise from active contributions to particle fluctuations which are unrelated to the dissipative resistance of the surrounding medium. We show that in these cases the widely used relation between informatic entropy production and heat dissipation does not hold. Consequently, fluctuation relations for the mechanical work, such as the Jarzynski and Crooks theorems, are invalid. We relate the breaking of the correspondence between entropy production and heat dissipation to departure from the fluctuation-dissipation theorem. We propose a temperaturelike variable that restores this correspondence and gives rise to a generalized second law of thermodynamics, whereby the dissipated heat is necessarily non-negative and vanishes at equilibrium. The Clausius inequality, Carnot maximum efficiency theorem, and relation between the extractable work and the change of free energy are recovered as well., Comment: 15 pages

Published

2024

2. Consistent expansion of the Langevin propagator with application to entropy production

Author

Sorkin, Benjamin, Ariel, Gil, and Markovich, Tomer

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Soft Condensed Matter

Abstract

Stochastic thermodynamics is a developing theory for systems out of thermal equilibrium. It allows to formulate a wealth of nontrivial relations among thermodynamic quantities such as heat dissipation, excess work, and entropy production in generic nonequilibrium stochastic processes. A key quantity for the derivation of these relations is the propagator - the probability to observe a transition from one point in phase space to another after a given time. Here, applying stochastic Taylor expansions, we devise a formal expansion procedure for the propagator of overdamped Langevin dynamics. The three leading orders are obtained explicitly. The technique resolves the shortcomings of the current mathematical machinery for the calculation of the propagator. For the evaluation of the first two displacement cumulants, the leading order Gaussian propagator is sufficient. However, some functionals of the propagator, such as the entropy production, which we refer to as "first derivatives of the trajectory", need to be evaluated to a previously-unrecognized higher order. The method presented here can be extended to arbitrarily higher orders in order to accurately compute any other functional of the propagator., Comment: 26 pages

Published

2024

3. Uphill drift in the absence of current in single-file diffusion

Author

Sorkin, Benjamin and Dean, David S.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Single-file diffusion is a paradigmatic model for the transport of Brownian colloidal particles in narrow one-dimensional channels, such as those found in certain porous media, where the particles cannot cross each other. We consider a system where a different external uniform potential is present to the right and left of an origin. For example, this is the case when two channels meeting at the origin have different radii. In equilibrium, the chemical potential of the particles are equal, the density is thus lower in the region with the higher potential, and by definition there is no net current in the system. Remarkably, a single-file tracer particle initially located at the origin, with position denoted by $Y(t)$, exhibits an average up-hill drift toward the region of highest potential. This drift has the late time behavior $\langle Y(t)\rangle= C t^{1/4}$, where the prefactor $C$ depends on the initial particle arrangement. This surprising result is shown analytically by computing the first two moments of $Y(t)$ through a simple and physically-illuminating method, and also via extensive numerical simulations., Comment: 17 pages, 10 figures

Published

2024

4. Single-file diffusion in spatially inhomogeneous systems

Author

Sorkin, Benjamin and Dean, David S.

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We study the effect of spatially-varying potential and diffusivity on the dispersion of a tracer particle in single-file diffusion. Non-interacting particles in such a system exhibit normal diffusion at late times, which is characterised by an effective diffusion constant $D_\mathrm{eff}$. Here we demonstrate the physically appealing result that the dispersion of single-file tracers in this system has the same long-time behavior as that for Brownian particles in a spatially-homogeneous system with constant diffusivity $D_\mathrm{eff}$. Our results are based on a late-time analysis of the Fokker-Planck equation, motivated by the mathematical theory of homogenization. The findings are confirmed by numerical simulations for both annealed and quenched initial conditions., Comment: 14 pages, 5 figures

Published

2023

5. Detecting and characterizing phase transitions in active matter using entropy

Author

Sorkin, Benjamin, Be'er, Avraham, Diamant, Haim, and Ariel, Gil

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics

Abstract

A major challenge in the study of active matter lies in quantitative characterization of phases and transitions between them. We show how the entropy of a collection of active objects can be used to classify regimes and spatial patterns in their collective behavior. Specifically, we estimate the contributions to the total entropy from correlations between the degrees of freedom of position and orientation. This analysis pin-points the flocking transition in the Vicsek model while clarifying the physical mechanism behind the transition. When applied to experiments on swarming Bacillus subtilis with different cell aspect ratios and overall bacterial area fractions, the entropy analysis reveals a rich phase diagram with transitions between qualitatively different swarm statistics. We discuss physical and biological implications of these findings., Comment: 18 pages, 5 figures. arXiv admin note: text overlap with arXiv:2208.05295

Published

2023

6. Universal Relation between Entropy and Kinetics

Author

Sorkin, Benjamin, Diamant, Haim, and Ariel, Gil

Subjects

Condensed Matter - Statistical Mechanics, Physics - Chemical Physics

Abstract

Relating thermodynamic and kinetic properties is a conceptual challenge with many practical benefits. Here, based on first principles, we derive a rigorous inequality relating the entropy and the dynamic propagator of particle configurations. It is universal and applicable to steady states arbitrarily far from thermal equilibrium. Applying the general relation to diffusive dynamics yields a relation between the entropy and the (normal or anomalous) diffusion coefficient. The relation can be used to obtain useful bounds for the late-time diffusion coefficient from the calculated steady-state entropy or, conversely, to estimate the entropy based on measured diffusion coefficients. We demonstrate the validity and usefulness of the relation through several examples and discuss its broad range of applications, in particular, for systems far from equilibrium., Comment: 20 pages, 6 figures

Published

2022

7. IJMC/FEF Student Research Competition: Toward a Fully Recycled Aluminum Alloy for Automotive Structural Applications

Author

Sims, Connor, Sorkin, Benjamin, Lange, Cory, and Moodispaw, Michael P.

Published

2024

8. Resolving entropy contributions in nonequilibrium transitions

Author

Sorkin, Benjamin, Ricouvier, Joshua, Diamant, Haim, and Ariel, Gil

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Soft Condensed Matter, Physics - Data Analysis, Statistics and Probability

Abstract

We derive a functional for the entropy contributed by any microscopic degrees of freedom as arising from their measurable pair correlations. Applicable both in and out of equilibrium, this functional yields the maximum entropy which a system can have given a certain correlation function. When applied to different correlations, the method allows us to identify the degrees of freedom governing a certain physical regime, thus capturing and characterizing dynamic transitions. The formalism applies also to systems whose translational invariance is broken by external forces and whose number of particles may vary. We apply it to experimental results for jammed bidisperse emulsions, capturing the crossover of this nonequilibrium system from crystalline to disordered hyperuniform structures as a function of mixture composition. We discover that the cross-correlations between the positions and sizes of droplets in the emulsion play the central role in the formation of the disordered hyperuniform states. We discuss implications of the approach for entropy estimation out of equilibrium and for characterizing transitions in disordered systems., Comment: 20 pages, 2 figures

Published

2022

9. Persistent Collective Motion of a Dispersing Membrane Domain

Author

Sorkin, Benjamin and Diamant, Haim

Subjects

Physics - Biological Physics, Condensed Matter - Soft Condensed Matter

Abstract

We study the Brownian motion of an assembly of mobile inclusions embedded in a fluid membrane. The motion includes the dispersal of the assembly, accompanied by the diffusion of its center of mass. Usually, the former process is much faster than the latter, since the diffusion coefficient of the center of mass is inversely proportional to the number of particles. However, in the case of membrane inclusions, we find that the two processes occur on the same time scale, thus prolonging significantly the lifetime of the assembly as a collectively moving object. This effect is caused by the quasi-two-dimensional membrane flows, which couple the motions even of the most remote inclusions in the assembly. The same correlations also cause the diffusion coefficient of the center of mass to decay slowly with time, resulting in weak sub-diffusion. We confirm our analytical results by Brownian dynamics simulations with flow-mediated correlations. The effect reported here should have implications for the stability of nano-scale membrane heterogeneities., Comment: 13 pages

Published

2020

10. Universal Relation between Entropy and Kinetics

Author

Sorkin, Benjamin, primary, Diamant, Haim, additional, and Ariel, Gil, additional

Published

2023

11. Resolving entropy contributions in nonequilibrium transitions

Author

Sorkin, Benjamin, primary, Ricouvier, Joshua, additional, Diamant, Haim, additional, and Ariel, Gil, additional

Published

2023

12. Detecting and characterizing phase transitions in active matter using entropy

Author

Sorkin, Benjamin, primary, Be’er, Avraham, additional, Diamant, Haim, additional, and Ariel, Gil, additional

Published

2023

13. Persistent collective motion of a dispersing membrane domain

Author

Sorkin, Benjamin, primary and Diamant, Haim, additional

Published

2021

14. THE BEST SCHOOLS INITIATIVE: A RESEARCH-DRIVEN APPROACH TO MAXIMIZING THE EFFICIENCY OF GLOBAL DEVELOPMENT IN INFORMAL SCHOOLS IN KIBERA, KENYA THROUGH TARGETED SCHOOL INTERVENTIONS AND EVALUATION

Author

Okoro, Jeffrey, primary and Sorkin, Benjamin, additional

Published

2020

15. Uphill Drift in the Absence of Current in Single-File Diffusion.

Author

Sorkin B and Dean DS

Abstract

Single-file diffusion is a paradigmatic model for the transport of Brownian colloidal particles in narrow one-dimensional channels, such as those found in certain porous media, where the particles cannot cross each other. We consider a system where a different external uniform potential is present to the right and left of an origin. For example, this is the case when two channels meeting at the origin have different radii. In equilibrium, the chemical potential of the particles are equal, the density is thus lower in the region with the higher potential, and by definition there is no net current in the system. Remarkably, a single-file tracer particle initially located at the origin, with position denoted by Y(t), exhibits an average uphill drift toward the region of highest potential. This drift has the late time behavior ⟨Y(t)⟩=Ct^{1/4}, where the prefactor C depends on the initial particle arrangement. This surprising result is shown analytically by computing the first two moments of Y(t) through a simple and physically illuminating method, and also via extensive numerical simulations.

Published

2024

16. Single-file diffusion in spatially inhomogeneous systems.

Author

Sorkin B and Dean DS

Abstract

We study the effect of spatially varying potential and diffusivity on the dispersion of a tracer particle in single-file diffusion. Noninteracting particles in such a system exhibit normal diffusion at late times, which is characterized by an effective diffusion constant D_{eff}. Here we demonstrate the physically appealing result that the dispersion of single-file tracers in this system has the same long-time behavior as that for Brownian particles in a spatially homogeneous system with constant diffusivity D_{eff}. Our results are based on a late-time analysis of the Fokker-Planck equation, motivated by the mathematical theory of homogenization. The findings are confirmed by numerical simulations for both annealed and quenched initial conditions.

Published

2023