Litcius/Paper detail

Mean-Field Caging in a Random Lorentz Gas

Giulio Biroli, Patrick Charbonneau, Yi Hu, Harukuni Ikeda, Grzegorz Szamel, Francesco Zamponi

2021The Journal of Physical Chemistry B22 citationsDOIOpen Access PDF

Abstract

The random Lorentz gas (RLG) is a minimal model of both percolation and glassiness, which leads to a paradox in the infinite-dimensional, d → ∞ limit: the localization transition is then expected to be continuous for the former and discontinuous for the latter. As a putative resolution, we have recently suggested that, as d increases, the behavior of the RLG converges to the glassy description and that percolation physics is recovered thanks to finite-d perturbative and nonperturbative (instantonic) corrections [Biroli et al. Phys. Rev. E 2021, 103, L030104]. Here, we expand on the d → ∞ physics by considering a simpler static solution as well as the dynamical solution of the RLG. Comparing the 1/d correction of this solution with numerical results reveals that even perturbative corrections fall out of reach of existing theoretical descriptions. Comparing the dynamical solution with the mode-coupling theory (MCT) results further reveals that, although key quantitative features of MCT are far off the mark, it does properly capture the discontinuous nature of the d → ∞ RLG. These insights help chart a path toward a complete description of finite-dimensional glasses.

Topics & Concepts

Lorentz transformationPhysicsPercolation (cognitive psychology)Limit (mathematics)Statistical physicsResolution (logic)Coupling (piping)Mathematical physicsClassical mechanicsMathematical analysisMathematicsComputer scienceNeuroscienceMechanical engineeringBiologyEngineeringArtificial intelligenceMaterial Dynamics and PropertiesTheoretical and Computational PhysicsAdvanced Neuroimaging Techniques and Applications