Energy-based, geometric, and compositional formulation of fluid and plasma models

TL;DR

This paper introduces a formal, energy-based modeling language for fluid and plasma systems that simplifies the composition, understanding, and analysis of complex multiphysics models, ensuring thermodynamic consistency.

Contribution

It presents the Exergetic Port-Hamiltonian Systems (EPHS) language, enabling modular, energy-based composition of fluid and plasma models with guaranteed thermodynamic properties.

Findings

Models can be composed from simpler parts using EPHS.

EPHS ensures conservation of energy and thermodynamic consistency.

Reusability of existing models as subsystems is demonstrated.

Abstract

Fluid dynamics plays a crucial role in various multiphysics applications, including energy systems, electronics cooling, and biomedical engineering. Developing models for complex coupled systems can be challenging and time-consuming. In particular, ensuring the consistent integration of models from diverse physical domains requires meticulous attention. Considering the example of (electro-)magneto hydrodynamics (on a fixed spatial domain and with linear polarization and magnetization), this article demonstrates how relatively complex models can be composed from simpler parts by means of a formal language for multiphysics modeling. The Exergetic Port-Hamiltonian Systems (EPHS) modeling language features a simple graphical syntax for expressing the energy-based interconnection of subsystems. This reduces cognitive load and facilitates communication, especially in multidisciplinary environments. As the example demonstrates, existing models can be easily integrated as subsystems of new models. Specifically, an ideal fluid model is used as a subsystem of a Navier-Stokes-Fourier fluid model, which in turn is reused as a subsystem of an (electro-)magneto hydrodynamics model. The energy-based, compositional approach simplifies understanding complex models, and it makes it easy to encapsulate, reuse, and replace (parts of) models. Moreover, structural properties of EPHS models guarantee fundamental properties of thermodynamic systems, such as conservation of energy, non-negative entropy production, and Onsager reciprocal relations.