A gradient-dynamics model for chemically driven running drops derives sustained self-propulsion from a maintained wettability contrast when distinct chemical potentials are imposed via chemostatting.
Title resolution pending
4 Pith papers cite this work. Polarity classification is still indexing.
years
2026 4verdicts
UNVERDICTED 4representative citing papers
Derives a corrected boundary condition that enforces exact total surfactant mass conservation in nonlinear reduced models of soluble-surfactant-laden falling films, resolving an inconsistency in prior surface transport reductions.
Laser-engraved channel networks on hardened cement paste enable rapid, directed capillary fluid propagation, achieving up to 10-fold greater wetted area, 180-fold better wetting efficiency, and up to 1.8°C cooler surfaces than untreated controls.
In dilute ternary Bose-Einstein condensates, the double-parabola approximation reliably captures nucleation transitions but matches full numerical results for wetting phase diagrams only in symmetric cases.
citing papers explorer
-
Gradient dynamics model for chemically driven running drops
A gradient-dynamics model for chemically driven running drops derives sustained self-propulsion from a maintained wettability contrast when distinct chemical potentials are imposed via chemostatting.
-
A conservation-consistent boundary condition for nonlinear models of soluble-surfactant-laden falling films
Derives a corrected boundary condition that enforces exact total surfactant mass conservation in nonlinear reduced models of soluble-surfactant-laden falling films, resolving an inconsistency in prior surface transport reductions.
-
Laser-Architected Surface Wetting
Laser-engraved channel networks on hardened cement paste enable rapid, directed capillary fluid propagation, achieving up to 10-fold greater wetted area, 180-fold better wetting efficiency, and up to 1.8°C cooler surfaces than untreated controls.
-
Influence of intraspecies interactions on the nucleation and wetting phase diagram in dilute ternary Bose-Einstein condensates
In dilute ternary Bose-Einstein condensates, the double-parabola approximation reliably captures nucleation transitions but matches full numerical results for wetting phase diagrams only in symmetric cases.