Abstract
A Lorentz transformation group SO(m, n) of signature (m, n), m, n ∈ N, in m time and n space dimensions, is the group of pseudo-rotations of a pseudo-Euclidean space of signature (m, n). Accordingly, the Lorentz group SO(1, 3) is the common Lorentz transformation group from which special relativity theory stems. It is widely acknowledged that special relativity and quantum theories are at odds. In particular, it is known that entangled particles involve Lorentz symmetry violation. We, therefore, review studies that led to the discovery that the Lorentz group SO(m, n) forms the symmetry group by which a multi-particle system of m entangled n-dimensional particles can be understood in an extended sense of relativistic settings. Consequently, we enrich special relativity by incorporating the Lorentz transformation groups of signature (m, 3) for all m ≥ 2. The resulting enriched special relativity provides the common symmetry group SO(1, 3) of the (1 + 3)-dimensional spacetime of individual particles, along with the symmetry group SO(m, 3) of the (m + 3)-dimensional spacetime of multi-particle systems of m entangled 3-dimensional particles, for all m ≥ 2. A unified parametrization of the Lorentz groups SO(m, n) for all m, n ∈ N, shakes down the underlying matrix algebra into elegant and transparent results. The special case when (m, n) = (1, 3) is supported experimentally by special relativity. It is hoped that this review article will stimulate the search for experimental support when (m, n) = (m, 3) for all m ≥ 2.
Highlights
Nature organizes itself using the language of symmetries
Review studies that led to the discovery that the Lorentz group SO(m, n) forms the symmetry group by which a multi-particle system of m entangled n-dimensional particles can be understood in an extended sense of relativistic settings
It is known that entangled particles in relativistic quantum mechanics involve Lorentz symmetry violation [1,2,3,4,5]
Summary
Nature organizes itself using the language of symmetries. in particular, the underlying symmetry group by which Einstein’s special relativity theory can be understood is the Lorentz group. The aim of this review article is, (i) to present results that demonstrate in extended relativistic settings that the Lorentz transformation groups SOc (m, n), m, n ∈ N, are the missing symmetry groups of multi-particle systems of entangled particles; and (ii) to stimulate the search for experimental support when m ≥ 2 and n = 3, in addition to the available experimental support when (m, n) = (1, 3) that Einstein’s. Following the induced interpretation for any m, n ∈ N, the Lorentz transformation group SOc (m, n) turns out to be the symmetry group of the (m + n)-dimensional spacetime of multi-particle systems that consist of m entangled n-dimensional particles. It is clear why quantum entanglement involves a violation of the Lorentz symmetry group. The symmetry group that controls multi-particle entanglement of m ≥ 2 particles is SOc (m, 3) rather than SOc (1, 3), as we demonstrate in this article in terms of mathematical analogies and patterns
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