A new derivation of the Minkowski metric

Chappell, James M.; Hartnett, John G.; Iannella, Nicolangelo; Iqbal, Azhar; Berkahn, David L.; Abbott, Derek

doi:10.1088/2399-6528/acd986

Cited by 3 publications

(1 citation statement)

References 31 publications

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“…Researchers have also taken a more mathematical approach to exploring the depths of the Minkowski metric. For instance, in Chappell et al (2023) [11], the authors presented a new derivation to the Minkowski metric. They demonstrated that the Minkowski metric could be obtained as an emergent property from physical space modeled as a Clifford algebra, Cl R 3 .…”

Section: Introductionmentioning

confidence: 99%

Relativistic Formulation in Dual Minkowski Spacetime

Ganesan

2024

Symmetry

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The objective of this work is to derive the structure of Minkowski spacetime using a Hermitian spin basis. This Hermitian spin basis is analogous to the Pauli spin basis. The derived Minkowski metric is then employed to obtain the corresponding Lorentz factors, potential Lie algebra, effects on gamma matrices and complex representations of relativistic time dilation and length contraction. The main results, a discussion of the potential applications and future research directions are provided.

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Section: Introductionmentioning

confidence: 99%

Relativistic Formulation in Dual Minkowski Spacetime

Ganesan

2024

Symmetry

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From colored gravity to electromagnetism

Monjo,

Rodríguez-Abella,

Campoamor-Stursberg

2024

Gen Relativ Gravit

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Quantum Entanglement Could Be the Result of Leptons, Quarks and Photons Simultaneously Experiencing 4-D Space as (3 + 1)-D Spacetime

Potter

2023

JMP

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We propose that quantum entanglement occurs because the fundamental particles, such as electrons, quarks, and photons, simultaneously experience both the 4 th real spatial dimension in R 4 as well as the time dimension in (3 + 1)-D spacetime. Consequently, the entangled particles can never become separated in the 4th spatial dimension no matter how far they have moved apart in the other 3 spatial dimensions. Because the quark and lepton families represent specific different discrete symmetry binary subgroups of SU(2), we can establish that the quantum states of the fundamental particles are defined in 4 spatial dimensions, so there is then no need for a spacetime communication from one detector (or particle) to inform the other detector (or particle) of the physical state of the first detected entangled particle. A clever experiment needs to determine whether the fundamental particles actually experience a 4th spatial dimension, and if so, whether they experience the 4th spatial dimension as the time dimension simultaneously. Apparently, if a Casimir-like test reveals that virtual particles have a non-zero mass, there are claims that a 4th spatial dimension does not exist.

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A new derivation of the Minkowski metric

Cited by 3 publications

References 31 publications

Relativistic Formulation in Dual Minkowski Spacetime

Relativistic Formulation in Dual Minkowski Spacetime

From colored gravity to electromagnetism

Quantum Entanglement Could Be the Result of Leptons, Quarks and Photons Simultaneously Experiencing 4-D Space as (3 + 1)-D Spacetime

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