Jamming transition in Couette shear

ORAL

Abstract

We study the jamming transition with a novel Couette experimental apparatus, which allows us to shear an ideal 2D photoelastic granular system. The photoelastic particles are suspended in a density matched fluid, so that there is no basal friction. We simultaneously record the particle positions and photoelastic response over a range of shear rates. The photoelastic data provide grain scale forces on the particles. The macroscale shear stress is obtained by a torque sensor. We study the correlation between the granular scale pressure from the photoelasic response, and macroscale shear stress during the shear jamming transition. We also determine the coarse-grained strain field, which shows novel convective flow over large strains.

*NSF DMR1206351, The William M Keck Foundation, and NASA grant NNX15AD38G

Presenters

  • Meimei Wang

    • Duke University; University of Science and Technology Beijing

Authors

  • Meimei Wang

    • Duke University; University of Science and Technology Beijing

  • Hu Zheng

    • Hohai University
    • Hohai University (currently Duke Univ.)
    • Dept. of Physics, Duke Univ
    • Duke University
    • Hohai University/Duke University
    • Physics, Duke University

  • Jonathan Bares

    • CNRS
    • Duke University; Universit'e de Montpellier
    • Physics, Duke University
    • Université de Montpellier

  • Dong Wang

    • Duke Univ
    • Duke University
    • Department of Physics, Duke Univ

  • Robert Behringer

    • Duke Univ
    • Physics, Duke University
    • Dept. of Physics, Duke Univ
    • Duke University
    • Department of Physics, Duke Univ
    • Physics Department, Duke Univ.
    • Phsyics, Duke University
    • Physics Department, Duke Univ