Viscous Taylor droplets in axisymmetric and planar tubes: from Bretherton’s theory to empirical models

The aim of this study is to derive accurate models for quantities characterizing the dynamics of droplets of non-vanishing viscosity in capillaries. In particular, we propose models for the uniform-film thickness separating the droplet from the tube walls, for the droplet front and rear curvatures and pressure jumps, and for the droplet velocity in a range of capillary numbers, Ca, from 10−4 to 1 and inner-to-outer viscosity ratios, λ, from 0, i.e. a bubble, to high-viscosity droplets. Theoretical asymptotic results obtained in the limit of small capillary number are combined with accurate numerical simulations at larger Ca. With these models at hand, we can compute the pressure drop induced by the droplet. The film thickness at low capillary numbers (Ca10−3.

Viscous Taylor droplets in axisymmetric and planar tubes: from Bretherton’s theory to empirical models

Effects of velocity-dependent apparent toughness on the pre- and post-shut-in growth of a hydraulic fracture

Fourier Collocation and Reduced Basis Methods for Fast Modeling of Compressible Flows

Effects of velocity-dependent apparent toughness on the pre- and post-shut-in growth of a hydraulic fracture

Fourier Collocation and Reduced Basis Methods for Fast Modeling of Compressible Flows