Atomes et matière : champs quantiques et mécanismes de résilience structurale

Key Points

The atomic medium continuously reorganizes to achieve a lower energy state, leading to structural resilience.
An inverse repulsive force is generated, reinforcing local stiffness proportional to deformation in atomic assemblies.
A theoretical framework is established, alongside mathematical formulations and various numerical test cases to validate findings.
Findings highlight significant implications for understanding inertia and wave propagation in materials at a macroscopic level.

Abstract

This theory describes the restructuring mechanisms of atomic assemblies shaped and sustained by quantum fields. Aiming for a lower energy state, the atomic medium continuously reorganizes, generating an inverse repulsive force and local stiffening proportional to deformation. These microscopic mechanisms give rise, at the macroscopic scale, to inertia, wave propagation, and Doppler energy effects. The following sections outline the theoretical framework, mathematical formulation, and forty-four numerical test cases (1D, 3D, Doppler and energy cost).

Atomes et matière : champs quantiques et mécanismes de résilience structurale

Key Points

Abstract

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