Existence of global entropy solution for Eulerian droplet models and two-phase flow model with non-constant air velocity

Abstract

This article addresses the question concerning the existence of global entropy solution for generalized Eulerian droplet models with air velocity depending on both space and time variables. When f(u)=u, (t)=const. and ua(x,t)=const. in (1.1), the study of the Riemann problem has been carried out by Keita and Bourgault [42] & Zhang et al. [38]. We show the global existence of the entropy solution to (1.1) for any strictly increasing function f(·) and ua(x,t) depending only on time with mild regularity assumptions on the initial data via shadow wave tracking approach. This represents a significant improvement over the findings of Yang [26]. Next, by using the generalized variational principle, we prove the existence of an explicit entropy solution to (1.1) with f(u)=u, for all time t>0 and initial mass v0>0, where ua(x,t) depends on both space and time variables, and also has an algebraic decay in the time variable. This improves the results of many authors such as Ha et al. [40], Cheng and Yang [27] & Ding and Wang [50] in various ways. Furthermore, by employing the shadow wave tracking procedure, we discuss the existence of global entropy solution to the generalized two-phase flow model with time-dependent air velocity that extends the recent results of Shen and Sun [9].

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