TL;DR
This paper develops a macromechanical framework from quantum mechanics, deriving classical and relativistic equations of motion, and explores dark matter systems and their spectral signatures in astrophysics.
Contribution
It introduces macromechanics, a novel formalism connecting quantum wave functions to macroscopic and dark matter dynamics, including new insights into dark particles and their spectral effects.
Findings
Derivation of Newtonian and relativistic equations from quantum mechanics.
Identification of negative pressure in dark ideal gases.
Proposal to detect dark particles via spectral line shifts in space.
Abstract
A wave function can be written in the form of {\psi} = ReiS/h. We put this form of wave function into quantum mechanics equations and take hydrodynamic limit, i. e., let Planck constant be zero. Then equations of motion (EOM) describing the movement of macroscopic bodies are retrieved. From Schrodinger equation, we obtain Newtonian mechanics, including Newtons three laws of motion; from decouple Klein-Gordon equation with positive kinetic energy (PKE), we obtain EOM of special relativity in classical mechanics. These are for PKE systems. From negative kinetic energy (NKE) Schrodinger equation and decoupled Klein-Gordon equation, the EOM describing low momentum and relativistic motions of macroscopic dark bodies are derived. These are NKE systems, i. e., dark systems. In all cases scalar and vector potentials are also taken into account. The formalism obtained is collectively called…
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