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Theoretical physicists working at a blackboard collaboration pod in the Beecroft building.
Credit: Jack Hobhouse

Ramin Golestanian FRS

Professor of Theoretical Condensed Matter Physics

Sub department

  • Rudolf Peierls Centre for Theoretical Physics

Research groups

  • Condensed Matter Theory
Ramin.Golestanian@physics.ox.ac.uk
Telephone: 01865 273974
Rudolf Peierls Centre for Theoretical Physics, room 60.12
Max Planck Institute for Dynamics and Self-Organization
Oxford Podcast (2014): Living Matter & Theo Phys
Oxford Podcast (2017): The bacterial Viewpoint
  • About
  • Teaching
  • Publications

Efficiency of navigation strategies for active particles in rugged landscapes

Frontiers in Physics Frontiers 10 (2022) 1034267

Authors:

Lorenzo Piro, Ramin Golestanian, Benoît Mahault
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Stress anisotropy in confined populations of growing rods

Journal of The Royal Society Interface The Royal Society 19:196 (2022) 20220512

Authors:

Jonas Isensee, Lukas Hupe, Ramin Golestanian, Philip Bittihn
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Catalysis-Induced Phase Separation and Autoregulation of Enzymatic Activity

Physical Review Letters American Physical Society (APS) 129:15 (2022) 158101

Authors:

Matthew W Cotton, Ramin Golestanian, Jaime Agudo-Canalejo
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Optimal navigation of microswimmers in complex and noisy environments

New Journal of Physics IOP Publishing 24:9 (2022) 093037-093037

Authors:

Lorenzo Piro, Benoît Mahault, Ramin Golestanian

Abstract:

We analyze long-time correlated Brownian motion and scaled Brownian motion on the surface of the two dimensional sphere $\mathbb{S}^{2}$. Due to the geometric effects induced by the $\mathbb{S}^{2}$ curvature, such correlations collude with specific dynamics (\emph{navigation strategies}) on the manifold topology to originate rich transport properties. We focus our study to two classes of navigation strategies: One induced by the specific set of coordinates chosen for $\mathbb{S}^2$ which defines a fixed frame of reference; in particular, we chose the basis induced by spherical coordinates. We find that contrary to what occurs in the absence of correlations non-equilibrium stationary distributions are attained. We elucidate an analogy of our results with those observed of fractional Brownian motion in confined by reflecting walls in one and two dimensions. In contrast, when the navigation strategy chosen corresponds to a frame of reference moving with the particle as does the Frenet-Serret system, then the equilibrium uniform distribution on the sphere is attained. In both cases, the relaxation times towards the stationary distribution depend on the particular value of the Hurst parameter. We show that scaled Brownian motion on $\mathbb{S}^2$ is independent of the navigation strategy and we find a good agreement between the analytical calculations obtained from the solution of a time-dependent diffusion equation on $\mathbb{S}^{2}$ and the numerical results obtained from our method to generate ensemble of trajectories.Comment: The statistics of Fractional Brownian motion and of scaled Brownian motion are analyzed when motion is constrained to surface of a spher
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Sustained unidirectional rotation of a self-organized DNA rotor on a nanopore

Nature Physics Springer Nature 18:9 (2022) 1105-1111

Authors:

Xin Shi, Anna-Katharina Pumm, Jonas Isensee, Wenxuan Zhao, Daniel Verschueren, Alejandro Martin-Gonzalez, Ramin Golestanian, Hendrik Dietz, Cees Dekker
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