Open AccessInhibition of wave-driven two-dimensional turbulence by viscoelastic films of proteins
Author(s) -
Nicolas François,
Hua Xia,
H. Punzmann,
Thomas Combriat,
Michael Shats
Publication year - 2015
Publication title -
physical review e
Language(s) - English
Resource type - Journals
eISSN - 1550-2376
pISSN - 1539-3755
DOI - 10.1103/physreve.92.023027
Subject(s) - viscoelasticity , turbulence , dispersion (optics) , materials science , surface wave , vorticity , adsorption , particle (ecology) , mechanics , shear (geology) , surface (topology) , chemical physics , physics , composite material , chemistry , optics , vortex , geology , oceanography , organic chemistry , geometry , mathematics
To model waves, surface flows, and particle dispersion at the air-water interface one needs to know the essential mechanisms affecting the fluid motion at the surface. We show that a thin film (less than 10-nm thick) of adsorbed protein dramatically affects two-dimensional turbulence generated by Faraday waves at the fluid surface. Extremely low concentrations (≈1 ppm) of soluble proteins form a strong viscoelastic layer which suppresses turbulent diffusion at the surface, changes wave patterns, and shows strong resilience to the wave-induced droplet generation. Surface shear properties of the film play a key role in this phenomenon by inhibiting the creation of vorticity at the surface. The addition of surfactants, on the other hand, destroys the nanolayer and restores the fluid mobility.
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