Dirac Field, van der Waals Gas, Weyssenhoff Fluid, and Newton Particle
Copyright policy )Dirac Field, van der Waals Gas, Weyssenhoff Fluid, and Newton Particle
This article considers the Dirac field in polar formulation and shows that when torsion is taken in effective approximation the theory has the thermodynamic properties of a van der Waals gas. It is then shown that in the limit of zero chiral angle the van der Waals gas reduces to a Weyssenhoff fluid, and in spinlessness regime the Weyssenhoff fluid further reduces to a Newton particle. This nesting of approximations allows us to interpret the various spinor quantities. We will see that torsion will provide a form of negative pressure, while the chiral angle will be related to a type of temperature.
- University of Genoa Italy
non-relativistic regime, Physics - General Physics, General Physics (physics.gen-ph), effective approximation, QA1-939, FOS: Physical sciences, classical limit, Mathematics, spinor field
non-relativistic regime, Physics - General Physics, General Physics (physics.gen-ph), effective approximation, QA1-939, FOS: Physical sciences, classical limit, Mathematics, spinor field
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