Why Do the Relativistic Masses and Momenta of Faster-than-Light Particles Decrease as their Speeds Increase?

Madarász, Judit X. and Stannett, Mike and Székely, Gergely (2014) Why Do the Relativistic Masses and Momenta of Faster-than-Light Particles Decrease as their Speeds Increase? SYMMETRY INTEGRABILITY AND GEOMETRY-METHODS AND APPLICATIONS, 10 (5). pp. 1-21. ISSN 1815-0659

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Abstract

It has recently been shown within a formal axiomatic framework using a definition of four-momentum based on the Stückelberg- Feynman-Sudarshan-Recami ''switching principle'' that Einstein's relativistic dynamics is logically consistent with the existence of interacting faster-than-light inertial particles. Our results here show, using only basic natural assumptions on dynamics, that this definition is the only possible way to get a consistent theory of such particles moving within the geometry of Minkowskian spacetime. We present a strictly formal proof from a streamlined axiom system that given any slow or fast inertial particle, all inertial observers agree on the value of m⋅|1−v2|−−−−−−√, where m is the particle's relativistic mass and v its speed. This confirms formally the widely held belief that the relativistic mass and momentum of a positive-mass faster- than-light particle must decrease as its speed increases.

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