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Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder.

Publication ,  Journal Article
Charbonneau, P; Corwin, EI; Dennis, RC; Díaz Hernández Rojas, R; Ikeda, H; Parisi, G; Ricci-Tersenghi, F
Published in: Physical review. E
July 2021

Jamming criticality defines a universality class that includes systems as diverse as glasses, colloids, foams, amorphous solids, constraint satisfaction problems, neural networks, etc. A particularly interesting feature of this class is that small interparticle forces (f) and gaps (h) are distributed according to nontrivial power laws. A recently developed mean-field (MF) theory predicts the characteristic exponents of these distributions in the limit of very high spatial dimension, d→∞ and, remarkably, their values seemingly agree with numerical estimates in physically relevant dimensions, d=2 and 3. These exponents are further connected through a pair of inequalities derived from stability conditions, and both theoretical predictions and previous numerical investigations suggest that these inequalities are saturated. Systems at the jamming point are thus only marginally stable. Despite the key physical role played by these exponents, their systematic evaluation has yet to be attempted. Here, we carefully test their value by analyzing the finite-size scaling of the distributions of f and h for various particle-based models for jamming. Both dimension and the direction of approach to the jamming point are also considered. We show that, in all models, finite-size effects are much more pronounced in the distribution of h than in that of f. We thus conclude that gaps are correlated over considerably longer scales than forces. Additionally, remarkable agreement with MF predictions is obtained in all but one model, namely near-crystalline packings. Our results thus help to better delineate the domain of the jamming universality class. We furthermore uncover a secondary linear regime in the distribution tails of both f and h. This surprisingly robust feature is understood to follow from the (near) isostaticity of our configurations.

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Published In

Physical review. E

DOI

EISSN

2470-0053

ISSN

2470-0045

Publication Date

July 2021

Volume

104

Issue

1-1

Start / End Page

014102

Related Subject Headings

  • 51 Physical sciences
  • 49 Mathematical sciences
  • 40 Engineering
 

Citation

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Charbonneau, P., Corwin, E. I., Dennis, R. C., Díaz Hernández Rojas, R., Ikeda, H., Parisi, G., & Ricci-Tersenghi, F. (2021). Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder. Physical Review. E, 104(1–1), 014102. https://doi.org/10.1103/physreve.104.014102
Charbonneau, Patrick, Eric I. Corwin, R Cameron Dennis, Rafael Díaz Hernández Rojas, Harukuni Ikeda, Giorgio Parisi, and Federico Ricci-Tersenghi. “Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder.Physical Review. E 104, no. 1–1 (July 2021): 014102. https://doi.org/10.1103/physreve.104.014102.
Charbonneau P, Corwin EI, Dennis RC, Díaz Hernández Rojas R, Ikeda H, Parisi G, et al. Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder. Physical review E. 2021 Jul;104(1–1):014102.
Charbonneau, Patrick, et al. “Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder.Physical Review. E, vol. 104, no. 1–1, July 2021, p. 014102. Epmc, doi:10.1103/physreve.104.014102.
Charbonneau P, Corwin EI, Dennis RC, Díaz Hernández Rojas R, Ikeda H, Parisi G, Ricci-Tersenghi F. Finite-size effects in the microscopic critical properties of jammed configurations: A comprehensive study of the effects of different types of disorder. Physical review E. 2021 Jul;104(1–1):014102.

Published In

Physical review. E

DOI

EISSN

2470-0053

ISSN

2470-0045

Publication Date

July 2021

Volume

104

Issue

1-1

Start / End Page

014102

Related Subject Headings

  • 51 Physical sciences
  • 49 Mathematical sciences
  • 40 Engineering