Explicit structure of the vanishing viscosity limits for the zero-pressure gas dynamics system initiated by the linear combination of a characteristic function and a $\delta$-distribution

TL;DR

This paper analyzes the vanishing viscosity limits of a zero-pressure gas dynamics system with initial data combining characteristic functions and delta measures, using Hopf-Cole transformations and asymptotic analysis of the erfc function.

Contribution

It provides a detailed analysis of the vanishing viscosity limits for a specific initial data configuration involving delta measures and characteristic functions in the zero-pressure gas dynamics system.

Findings

Explicit description of vanishing viscosity limits.

Use of Hopf-Cole transformations for analysis.

Asymptotic properties of erfc function applied.

Abstract

In this article, we consider the one-dimensional zero-pressure gas dynamics system \[ u_t + \left( {u^2}/{2} \right)_x = 0,\ \rho_t + (\rho u)_x = 0 \] in the upper-half plane with a linear combination of a characteristic function and a $\delta$-measure \[ u|_{t=0} = u_a\ \chi_{ {}_{ \left( -\infty , a \right) } } + u_b\ \delta_{x=b},\ \rho|_{t=0} = \rho_c\ \chi_{ {}_{ \left( -\infty , c \right) } } + \rho_d\ \delta_{x=d} \] as initial data, where $a$, $b$, $c$, $d$ are distinct points on the real line ordered as $a < c < b < d$, and provide a detailed analysis of the vanishing viscosity limits for the above system utilizing the corresponding modified adhesion model \[ u^\epsilon_t + \left({(u^\epsilon)^2}/{2} \right)_x =\frac{\epsilon}{2} u^\epsilon_{xx},\ \rho^\epsilon_t + (\rho^\epsilon u^\epsilon)_x = \frac{\epsilon}{2} \rho^\epsilon_{xx}. \] For this purpose, we use suitable Hopf-Cole transformations and various asymptotic properties of the function erfc$: z \longmapsto \int_{z}^{\infty} e^{-s^2}\ ds$.