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Structure and Dynamics of Disclination Loops and Lines in 3D Active Nematic Flows

POSTER

Abstract

Topological defects are essential to the chaotic self-stirring of active nematics, whose internally driven flows couple to orientational distortions. However, while the 2D case is well-studied, in 3D the nematic topological defects become much more complex, including curvilinear disclinations of variable winding character. To understand 3D active nematic flow dynamics, we present calculations of active hydrodynamics with nematic elasticity, together with topological analysis of data from the first experiments on bulk 3D active nematics. We show that the dominant topological excitations are a certain geometrical family of topologically neutral closed-loop disclinations, which move, deform, reconnect, and self-annihilate under the flow fields that they generate.

Authors

  • Daniel Beller

    University of California, Merced

  • Guillaume Duclos

    Brandeis University

  • Raymond Adkins

    University of California, Santa Barbara

  • Debarghya Banerjee

    Max Planck Institute for Dynamics and SelfOrganization and Universiteit Leiden

  • Matthew Peterson

    Brandeis University

  • Minu Varghese

    Brandeis University

  • Itamar Kolvin

    University of California, Santa Barbara

  • Arvind Baskaran

    Brandeis University

  • Robert Pelcovits

    Brown University, Department of Physics, Brown University, Providence, Rhode Island 02912

  • Thomas Powers

    Brown University

  • Aparna Baskaran

    Brandeis University

  • Federico Toschi

    Eindhoven University of Technology, Eindhoven University of Technology, The Netherlands

  • Michael Hagan

    Brandeis University

  • Sebastian Streichan

    University of California, Santa Barbara

  • Vincenzo Vitelli

    University of Chicago

  • Zvonimir Dogic

    Brandeis University