Global existence of the Navier-Stokes-Korteweg equations with a non-decreasing pressure in Lp-framework

Abstract

We consider the isentropic Navier-Stokes-Korteweg equations with a non-decreasing pressure on the whole space Rn (n 2), where the system describes the motion of compressible fluids such as liquid-vapor mixtures with phase transitions including a variable internal capillarity effect. We prove the existence of a unique global strong solution to the system in the Lp-in-time and Lq-in-space framework, especially in the maximal regularity class, by assuming (p, q) ∈ (1, 2) × (1, ∞) or (p, q) ∈ \2\ × (1, 2]. We show that the system is globally well-posed for small initial data belonging to Hs + 1, q (Rn) × Hs, q (Rn)n provided s > n/q if q n and s 1 if q > n. Our results allow the case when the derivative of the pressure is zero at a given constant state, that is, the critical states that the fluid changes a phase from vapor to liquid or from liquid to vapor. The arguments in this paper do not require any exact expression or a priori assumption on the pressure.