Author(s): Alessandro Lenci; Sepideh Majdabadi Farahani; Luca Chiapponi; Vittorio Di Federico; Sandro Longo

Linked Author(s): Vittorio Di Federico

Keywords: Gravity currents; Porous media; Forchheimer flow; Self-similar solution

Abstract: We consider an axisymmetric gravity current of a Newtonian fluid advancing through an infinite, homogeneous porous medium characterized by an effective porosity ϕ and hydraulic conductivity K. The flow regime is governed by Forchheimer’s law, which establishes a quadratic relationship between the velocity and the head gradient through the coefficient b. An integral-type inflow boundary condition is imposed, such that the volume of the current increases as a power law in time with exponent α. We derive a self-similar solution describing the water table profile, which can be obtained by numerically integrating a non-linear ordinary differential equation. In the case of a finite volume release of a fluid (α=0), the solution is analytical. This enables us to determine the gravity current profile as a function of the problem parameters. Notably, the current decelerates for α 3. Furthermore, we derive and discuss the aspect ratio of the current, its average slope, and the slope of the current in the box-model approximation. The box-model yields a dimensionless threshold time beyond which neglecting the Darcy term in the seepage equation is justified; this threshold time is found to depend on α and on the parameter B=K^2*b. Examples of both dimensionless and dimensional threshold times, computed from experimental data, are reported.

DOI: https://doi.org/10.64697/978-90-835589-7-4_41WC-P1554-cd

Year: 2025