Dirac-Type Equations in a Gravitational Field, with Vector Wave Function

Foundations of Physics 38 (11):1020-1045 (2008)
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Abstract

An analysis of the classical-quantum correspondence shows that it needs to identify a preferred class of coordinate systems, which defines a torsionless connection. One such class is that of the locally-geodesic systems, corresponding to the Levi-Civita connection. Another class, thus another connection, emerges if a preferred reference frame is available. From the classical Hamiltonian that rules geodesic motion, the correspondence yields two distinct Klein-Gordon equations and two distinct Dirac-type equations in a general metric, depending on the connection used. Each of these two equations is generally-covariant, transforms the wave function as a four-vector, and differs from the Fock-Weyl gravitational Dirac equation (DFW equation). One obeys the equivalence principle in an often-accepted sense, whereas the DFW equation obeys that principle only in an extended sense

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10.1007/s10701-008-9249-6

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Mayeul Arminjon
Institut National Polytechnique de Grenoble

Citations of this work

On the Second Dipole Moment of Dirac’s Particle.Engel Roza - 2020 - Foundations of Physics 50 (8):828-849.

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Erratum.[author unknown] - 2017 - British Journal for the History of Philosophy 25 (3):1-1.

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