English

Multi-Symplectic Lagrangian, One-Dimensional Gas Dynamics

Mathematical Physics 2015-05-20 v4 math.MP

Abstract

The equations of Lagrangian, ideal, one-dimensional (1D), compressible gas dynamics are written in a multi-symplectic form using the Lagrangian mass coordinate mm and time tt as independent variables, and in which the Eulerian position of the fluid element x=x(m,t)x=x(m,t) is one of the dependent variables. This approach differs from the Eulerian, multi-symplectic approach using Clebsch variables. Lagrangian constraints are used to specify equations for xmx_m, xtx_t and StS_t consistent with the Lagrangian map, where SS is the entropy of the gas. We require St=0S_t=0 corresponding to advection of the entropy SS with the flow. We show that the Lagrangian Hamiltonian equations are related to the de Donder-Weyl multi-momentum formulation. The pullback conservation laws and the symplecticity conservation laws are discussed. The pullback conservation laws correspond to invariance of the action with respect to translations in time (energy conservation) and translations in mm in Noether's theorem. The conservation law due to mm-translation invariance gives rise to a novel nonlocal conservation law involving the Clebsch variable rr used to impose S(m,t)/t=0\partial S(m,t)/\partial t=0. Translation invariance with respect to xx in Noether's theorem is associated with momentum conservation. We obtain the Cartan-Poincar\'e form for the system, and use it to obtain a closed ideal of two-forms representing the equation system.

Keywords

Cite

@article{arxiv.1408.4028,
  title  = {Multi-Symplectic Lagrangian, One-Dimensional Gas Dynamics},
  author = {G. M. Webb},
  journal= {arXiv preprint arXiv:1408.4028},
  year   = {2015}
}

Comments

36 pages

R2 v1 2026-06-22T05:32:11.162Z