On the Mathematical Analysis and Physical Implications of the Principle of Minimum Pressure Gradient

TL;DR

This paper establishes a variational principle linking the Navier-Stokes equations to the minimization of pressure forces, offering new insights into flow behavior and stability in incompressible fluid dynamics.

Contribution

It proves the equivalence between the Navier-Stokes equations and the principle of minimum pressure gradient, providing a new variational perspective and generalizing classical Galerkin methods.

Findings

PMPG is equivalent to Navier-Stokes solutions.

PMPG generalizes Galerkin projection to nonlinear modes.

Connections between flow minimization and stability conjectures.

Abstract

In this paper, we establish a two-way equivalence between the incompressible Navier- Stokes equation (INSE) and the principle of minimum pressure gradient (PMPG). We prove that a candidate smooth flow field is a solution of the INSE if and only if its instantaneous evolution minimizes, at every instant, the norm of the pressure force, required to enforce incompressibility. We show that the PMPG is precisely the minimization formulation of the Leray-Helmholtz projection. Any admissible instantaneous evolution (e.g., onset of separation) resulting from the INSE necessarily minimizes the PMPG cost. Conversely, any other kinematically admissible evolution, requiring a strictly larger pressure force to ensure the same constraints, does not satisfy the INSE. Thus, the PMPG offers a variational perspective through which intricate incompressible flow behaviors may be interpreted. In a finite-dimensional setting with divergence-free modes, we show that the PMPG yields the same dynamics as classical Galerkin projection. Moreover, the PMPG provides a natural generalization of classical Galerkin projection beyond linear modal expansions, accommodating nonlinear and non-modal representations. We then examine the relation between instantaneous dynamical minimization and steady variational selection, including its connection to the variational theory of lift. Motivated by these observations, we formulate conjectures concerning necessary conditions for stability and the convergence of Navier-Stokes solutions to Euler's in the vanishing-viscosity limit.