The d'Alembert-lagrange principle for gradient theories and boundary conditions

TL;DR

This paper extends the d'Alembert-Lagrange principle to gradient theories of continuous media, enabling better modeling of singularities like interfaces and shocks without discontinuities, with applications to capillary fluids.

Contribution

It reformulates the principle of virtual work for gradient-based models, allowing for boundary conditions and equations that handle singular zones more accurately.

Findings

Higher-order equations capture singular zones with physical thickness

Gradient models facilitate numerical and asymptotic analysis

Application to capillary fluids demonstrates practical benefits

Abstract

Motions of continuous media presenting singularities are associated with phenomena involving shocks, interfaces or material surfaces. The equations representing evolutions of these media are irregular through geometrical manifolds. A unique continuous medium is conceptually simpler than several media with surfaces of singularity. To avoid the surfaces of discontinuity in the theory, we transform the model by considering a continuous medium taking intoaccount more complete internal energies expressed in gradient developments associated with the variables of state. Nevertheless, resulting equations of motion are of an higher order than those of the classical models: they lead to non-linear models associated with more complex integration processes on the mathematical level as well as on the numerical point of view. In fact, such models allow a precise study of singular zones when they have a non negligible physical thickness. This is typically the case for capillarity phenomena in fluids or mixtures of fluids in which interfacial zones are transition layers between phases or layers between fluids and solid walls. Within the framework of mechanics for continuous media, we propose to deal with the functional point of view considering globally the equations of the media as well as the boundary conditions associated with these equations. For this aim, we revisit the d'Alembert-Lagrange principle of virtual works which is able to consider the expressions of the works of forces applied to a continuous medium as a linear functional value on a space of test functions in the form of virtual displacements. At the end, we analyze examples corresponding to capillary fluids. This analysis brings us to numerical or asymptotic methods avoiding the difficulties due to singularities in simpler -but with singularities- models.