First Principles Magnetohydrodynamical Theory for the Expanding Box Model

arXiv:2606.10283v1 Announce Type: new Abstract: The Expanding Box Model (EBM) has been widely employed to simulate multiscale plasma phenomena in the expanding solar wind by transforming the MHD equations to a co-moving, non-inertial frame. However, traditional formulations have suffered from historical ambiguity regarding the physical separation between the co-moving and inertial reference frames, primarily arising from a classical approximation of an invariant magnetic field between them. To resolve this inconsistency, we reformulate the EBM from first principles using a fully covariant approach. Here, we model the expanding solar wind frame as an anisotropic expanding spacetime metric, allowing us to incorporate radial acceleration profiles and differential transverse expansion, ensuring that all physical fields are correctly transformed by expansion. We demonstrate that the mathematical artifacts and structural asymmetries identified in previous EBM-MHD literature are direct consequences of neglecting the tensorial scaling of the magnetic field. Our covariant treatment eliminates these residues, restoring symmetry in the co-moving frame. Projecting our system back into the inertial frame recovers the established observational scaling and analogous physics, clarifies the mathematical distinction between local plasma dynamics and global expansion, and reveals the macroscopic anisotropy of the Parker spiral as a purely geometric projection. Furthermore, linear wave analysis demonstrates that macroscopic acceleration governs the evolution of Alfv\'en wave amplitude, acting either as geometric damping or as an energy source. Further, we write the EBM-MHD system using compressible Els\"asser variables. This formulation provides a consistent and clean foundation for future numerical simulations of accelerating astrophysical plasmas.