Condensed Matter Theory

On generalized Q-systems

Journal of High Energy Physics Springer Nature 2020:3 (2020) 177

Authors:

Zoltán Bajnok, Etienne Granet, Jesper Lykke Jacobsen, Rafael I Nepomechie

On zero-remainder conditions in the Bethe ansatz

Journal of High Energy Physics Springer Nature 2020:3 (2020) 178

Authors:

Etienne Granet, Jesper Lykke Jacobsen

Large Classes of Quantum Scarred Hamiltonians from Matrix Product States

(2020)

Authors:

Sanjay Moudgalya, Edward O'Brien, B Andrei Bernevig, Paul Fendley, Nicolas Regnault

Social Cooperativity of Bacteria during Reversible Surface Attachment in Young Biofilms: a Quantitative Comparison of Pseudomonas aeruginosa PA14 and PAO1

mBio American Society for Microbiology 11:1 (2020) 10.1128/mbio.02644-10.1128/mbio.02619

Authors:

Calvin K Lee, Jérémy Vachier, Jaime de Anda, Kun Zhao, Amy E Baker, Rachel R Bennett, Catherine R Armbruster, Kimberley A Lewis, Rebecca L Tarnopol, Charles J Lomba, Deborah A Hogan, Matthew R Parsek, George A O’Toole, Ramin Golestanian, Gerard CL Wong

Active matter in a viscoelastic environment

Physical Review Fluids American Physical Society 5:2020 (2020) 023102

Authors:

Emmanuel Plan, Julia Yeomans, Amin Doostmohammadi

Abstract:

Active matter systems such as eukaryotic cells and bacteria continuously transform chemical energy to motion. Hence living systems exert active stresses on the complex environments in which they reside. One recurring aspect of this complexity is the viscoelasticity of the medium surrounding living systems: bacteria secrete their own viscoelastic extracellular matrix, and cells constantly deform, proliferate, and self-propel within viscoelastic networks of collagen. It is therefore imperative to understand how active matter modifies, and gets modified by, viscoelastic fluids. Here, we present a two-phase model of active nematic matter that dynamically interacts with a passive viscoelastic polymeric phase and perform numerical simulations in two dimensions to illustrate its applicability. Motivated by recent experiments we first study the suppression of cell division by a viscoelastic medium surrounding the cell. We further show that the self-propulsion of a model keratocyte cell is modified by the polymer relaxation of the surrounding viscoelastic fluid in a non-uniform manner and find that increasing polymer viscosity effectively suppresses the cell motility. Lastly, we explore the hampering impact of the viscoelastic medium on the generic hydrodynamic instabilities of active nematics by simulating the dynamics of an active stripe within a polymeric fluid. The model presented here can provide a framework for investigating more complex dynamics such as the interaction of multicellular growing systems with viscoelastic environments.