Publications

Submitted

  1. Nonlinear electrohydrodynamics of a surfactant-laden leaky dielectric drop
    M. A. McDougall, S. K. Wilson, and D. Das. arXiv:2602.02971
  2. Nonlinear three-dimensional electrohydrodynamic interactions of viscous dielectric drops
    M. A. McDougall, S. K. Wilson, and D. Das. arXiv:2505.10986

Published

  1. Rolling at right angles: magnetic anisotropy enables dual-anisotropic active matter
    E. Fitzgerald, C. Clavaud, D. Das, I. C. Lenton, and S. R. Waitukaitis, Phys. Rev. E, 112, 065418, 2025.
  2. Cilia dynamics create a dynamic barrier to penetration of the periciliary layer in human airway epithelia
    E. Causa, D. Das, L. Feriani, J. Kotar, and P. Cicuta, Proc. Natl. Acad. Sci. USA, 122, e2419032122, 2025.
  3. Hydrodynamic hovering of swimming bacteria above surfaces
    P. H. Htet, D. Das, and E. Lauga, Phys. Rev. Research, 6, L032070, 2024.
  4. On the absence of collective motion in a bulk suspension of spontaneously rotating dielectric particles
    D. Das and D. Saintillan, Soft Matter, 19, 6825–6837, 2023.
  5. Flow field disturbance due to point viscosity variations in a heterogeneous fluid
    D. Das, Phys. Rev. Fluids, 8, L051301, 2023.
  6. Influence of surface viscosities on the electrodeformation of a prolate viscous drop
    H. Nganguia, D. Das, O. S. Pak, and Y.-N. Young, Soft Matter, 19, 776–789, 2023.
  7. A three-dimensional small-deformation theory for electrohydrodynamics of dielectric drops
    D. Das and D. Saintillan, J. Fluid Mech., 914, A22, 2021.
  8. Cilia density and flow velocity affect alignment of motile cilia from brain cells
    N. Pellicciotta, D. Das, J. Kotar, M. Faucourt, N. Spassky, E. Lauga, and P. Cicuta, J. Exp. Biol., 223, 24, 2020.
  9. Transition to bound states for bacteria swimming near surfaces
    D. Das and E. Lauga, Phys. Rev. E, 100, 043117, 2019.
  10. Active particles powered by Quincke rotation in a bulk fluid
    D. Das and E. Lauga, Phys. Rev. Lett., 122, 194503, 2019.
  11. Self-organization of swimmers drives long-range fluid transport in bacterial colonies
    H. Xu, J. Dauparas, D. Das, E. Lauga, and Y. Wu, Nat. Commun., 10, 1792, 2019.
  12. Computing the motor torque of Escherichia coli
    D. Das and E. Lauga, Soft Matter, 14, 5955–5967, 2018.
  13. Swimming of peritrichous bacteria is enabled by an elastohydrodynamic instability
    E. E. Riley*, D. Das*, and E. Lauga, Sci. Rep., 8, 10728, 2018.
  14. Helical micropumps near surfaces
    J. Dauparas, D. Das, and E. Lauga, Biomicrofluidics, 12, 014108, 2018.
  15. Electrohydrodynamics of viscous drops in strong electric fields: numerical simulations
    D. Das and D. Saintillan, J. Fluid Mech., 829, 127–152, 2017.
  16. A nonlinear small-deformation theory for transient droplet electrohydrodynamics
    D. Das and D. Saintillan, J. Fluid Mech., 810, 225–253, 2017.
  17. Emergent vortices in populations of colloidal rollers
    A. Bricard, J.-B. Caussin, D. Das, C. Savoie, V. Chikkadi, K. Shitara, O. Chepizhko, F. Peruani, D. Saintillan, and D. Bartolo, Nat. Commun., 6, 7470, 2015.
  18. Electrohydrodynamic interaction of spherical particles under Quincke rotation
    D. Das and D. Saintillan, Phys. Rev. E, 87, 043014, 2013.