Bulletin of the American Physical Society
76th Annual Meeting of the Division of Fluid Dynamics
Sunday–Tuesday, November 19–21, 2023; Washington, DC
Session T39: Interfacial Phenomena I
4:25 PM–5:56 PM,
Monday, November 20, 2023
Room: 204B
Chair: Fernando Temprano-Coleto, Princeton University
Abstract: T39.00005 : Exogenous-endogenous surfactant iteraction yields heterogenous spreading in complex branching networks
5:17 PM–5:30 PM
Presenter:
Richard Mcnair
(University of Manchester)
Authors:
Richard Mcnair
(University of Manchester)
Fernando Temprano-Coleto
(Princeton University)
Frederic Gibou
(University of California, Santa Barbara)
Paolo Luzzatto-Fegiz
(University of California, Santa Barbara)
François J Peaudecerf
(University of Rennes)
Oliver E Jensen
(University of Manchester)
Julien R Landel
(Univ of Manchester)
Experiments1 have shown that surfactant introduced at the entrance of a maze filled with a shallow layer of milk can induce a flow in the liquid which spontaneously finds the solution path, effectively solving the maze with minimal flow into dead-end sections. Here, we test the hypothesis that this maze-solving behaviour is due to the dynamics of a second species of surfactant endogenous to the liquid. Lubrication theory can be used to derive equations capturing the Marangoni flow induced by surfactants, which reduce to a nonlinear diffusion equation2 describing the spread of the exogenous surfactant in a large-gravity and low-Reynolds-number limit. Treating both species of surfactant as a single concentration field, we solve this equation simultaneously with a kinematic equation to track the exogenous front locations.
To solve the governing equation on a network representing the topology of the maze, we construct a mass-conserving mimetic-finite-difference (MFD) scheme using tools from discrete calculus and graph theory. We find that the simulation qualitatively captures the maze-solving behaviour observed in the experiment, with the result dependent on only two fitting parameters: the mass ratio of exogenous to endogenous surfactant, and the initial ratio of the surfactant concentrations. A modal decomposition of the MFD Laplacian operator shows that only three dominant modes are needed to qualitatively capture the key behaviour of maze solving, and the experimentally observed behaviour of receding in dead end sections.
1 Temprano-Coleto et al., Phys Rev Fluids. 3, 100507 (2018)
2 Jensen and Halpern, J. Fluid Mech. 372, 273 (1998)
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