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Advanced filters: Author: Sujit Datta Clear advanced filters

  • Sujit Datta demonstrates how scaling arguments, thermodynamics and transport phenomena can be deployed to describe the motion of microbial collectives.

    • Sujit Datta
    Comments & Opinion
    Nature Chemical Engineering
    Volume: 2, P: 90

  • Sujit Datta discusses how scaling arguments, dimensional analysis and chemical engineering fundamentals can be used to describe microbial swimming.

    • Sujit S. Datta
    Comments & Opinion
    Nature Chemical Engineering
    Volume: 1, P: 787

  • Liquid–liquid phase separation is known in cell biology as an underlying mechanism of intracellular organization. The authors study a complex interplay between phase separation, network mechanics, and condensate capillarity, providing explanation for the phenomena in complex environments like the cellular interior.

    • Jason X. Liu
    • Mikko P. Haataja
    • Rodney D. Priestley
    ResearchOpen Access
    Nature Communications
    Volume: 14, P: 1-10

  • Most bacteria exist in dense aggregates, yet this lifestyle is relatively poorly understood compared with planktonic cultures. This Review explores biophysical models of aggregate development, and how models can be extended to account for the complex behaviours of single-species and multispecies colonies.

    • Rachel Porter
    • Carolina Trenado-Yuste
    • Kerwyn Casey Huang
    Reviews
    Nature Reviews Physics
    Volume: 7, P: 535-553

  • Navigation through porous environments poses a major challenge for swimming microorganisms and future microrobots. This study predicts that their spreading becomes optimal when their run length is comparable to the longest available pore length.

    • Christina Kurzthaler
    • Suvendu Mandal
    • Howard A. Stone
    ResearchOpen Access
    Nature Communications
    Volume: 12, P: 1-10

  • Many bacteria swim with run-and-tumble motion in unconfined fluid. Here the authors report that confinement of these bacteria in a 3D porous medium changes this motion into hopping and trapping, in which the cells are intermittently and transiently trapped as they navigate the pore space.

    • Tapomoy Bhattacharjee
    • Sujit S. Datta
    ResearchOpen Access
    Nature Communications
    Volume: 10, P: 1-9

  • Active matter locally dissipates energy to produce systematic motion. This Perspective highlights proliferation as a special type of activity that breaks particle number conservation and thereby gives rise to a unique set of collective phenomena characteristic of life.

    • Oskar Hallatschek
    • Sujit S. Datta
    • Ned S. Wingreen
    Reviews
    Nature Reviews Physics
    Volume: 5, P: 407-419