Examining capillary dynamics in rectangular and circular conduits subject to unsteady surface tension

The unsteady effects of transitioning surface tension, gamma(t), on the dynamics of capillary imbibition in channels of arbitrary shape are analytically investigated with a focus on rectangular and circular channels. With proper scaling, two unsteady models for gamma(t) are defined and used to highlight this transient behaviour. The convoluted dynamics at the flow front are correctly captured in the governing equations, which are rigorously analysed using unsteady eigenfunction expansion. Then, the final solution and data are obtained by employing the Runge-Kutta fourth-order scheme elegantly applied simultaneously to two derived nonlinear ordinary differential equations. Ultimately, the results are more accurate compared with previous studies. Dynamics and kinematic similarity between rectangular and circular channels are investigated and discussed and the conditions for equivalence in both channels are highlighted. Using a small parameter (epsilon) that stretches the time scale, we successfully use a robust asymptotic analysis to develop and capture the long-time dynamics. Ultimately, we recover the Lucas-Washburn regime analysed in Washburn (Phys. Rev., vol. 17, 1921, pp. 273-283), Lucas (Kolloidn. Z., vol. 23, 1918, pp. 15-22) for steady surface tension where the variations of depth and rate with time result in h similar to t(1/2) and v similar to t(-1/2). In the end, the three forces, namely the inertia, F-v, the viscous, F-mu, and the surface tension, F-gamma, are briefly analysed and used to highlight three main distinct regimes. We show that at early times, F-v/F-gamma similar to 1, whereas at a long time, F-mu/F-gamma similar to-1.

Automated summary

This article analytically investigates the effects of transitioning surface tension on the dynamics of capillary imbibition in channels of arbitrary shape, with a focus on rectangular and circular channels. Two unsteady models for the transitioning surface tension are defined and used to highlight the transient behavior. The governing equations are rigorously analyzed using unsteady eigenfunction expansion, and the final solution and data are obtained employing the Runge-Kutta fourth-order scheme. The results are more accurate compared with previous studies. The dynamics and kinematic similarity between rectangular and circular channels are investigated, and the conditions for equivalence in both channels are highlighted.