Split quaternions and particles in (2+1)-space

Gogberashvili, Merab

doi:10.1140/epjc/s10052-014-3200-0

Cited by 21 publications

(20 citation statements)

References 29 publications

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“…are called the scalar and vector parts of octonion, respectively. Similar to the case of split quaternions [46,56], there exist three classes of split octonions having positive, negative or zero norm,…”

Section: Resultsmentioning

confidence: 99%

Geometrical Applications of Split Octonions

Gogberashvili

Sakhelashvili

2015

Advances in Mathematical Physics

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It is shown that physical signals and space-time intervals modeled on split-octonion geometry naturally exhibit properties from conventional (3+1)-theory (e.g. number of dimensions, existence of maximal velocities, Heisenberg uncertainty, particle generations, etc.). This paper demonstrates these properties using an explicit representation of the automorphisms on split-octonions, the noncompact form of the exceptional Lie group G2. This group generates specific rotations of (3+4)-vector parts of split octonions with three extra time-like coordinates and in infinitesimal limit imitate standard Poincare transformations. In this picture translations are represented by non-compact Lorentz-type rotations towards the extra time-like coordinates. It is shown how the G2 algebra's chirality yields an intrinsic left-right asymmetry of a certain 3-vector (spin), as well as a parity violating effect on light emitted by a moving quantum system. Elementary particles are connected with the special elements of the algebra which nullify octonionic intervals. Then the zero-norm conditions lead to free particle Lagrangians, which allow virtual trajectories also and exhibit the appearance of spatial horizons governing by mass parameters.

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Section: Resultsmentioning

confidence: 99%

Geometrical Applications of Split Octonions

Gogberashvili

Sakhelashvili

2015

Advances in Mathematical Physics

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“…For geometrical applications, we can define the line element in the space of split quaternions in the form [6]:…”

Section: Merab Gogberashvilimentioning

confidence: 99%

“…It is known that ordinary (Hamilton's) and split quaternions can be used to describe 3-dimensional Euclidean and Minkowski spaces, respectively. Here we consider vector and spinor representations in (2+2)-space of split quaternions, which generates kinematics of 3-dimensional Minkowski space-times [6].…”

Section: Introductionmentioning

confidence: 99%

Split-Quaternion Analyticity and (2 + 1)-Electrodynamics

Gogberashvili¹

2021

Proceedings of RDP Online Workshop "Recent Advances in Mathematical Physics" — PoS(Regio2020)

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“…Although this assumption is qualified by the fact that time contributes an opposite sign to the metric distance and so distinct from a regular fourdimensional Cartesian vector. Note that the octonions, being the generalization of quaternions, have also been considered as an expanded arena for spacetime [9][10][11][12].…”

Section: Algebraic Formulations Of Timementioning

confidence: 99%

Time As a Geometric Property of Space

et al. 2016

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The proper description of time remains a key unsolved problem in science. Newton conceived of time as absolute and universal which "flows equably without relation to anything external." In the nineteenth century, the four-dimensional algebraic structure of the quaternions developed by Hamilton, inspired him to suggest that he could provide a unified representation of space and time. With the publishing of Einstein's theory of special relativity these ideas then lead to the generally accepted Minkowski spacetime formulation of 1908. Minkowski, though, rejected the formalism of quaternions suggested by Hamilton and adopted an approach using four-vectors. The Minkowski framework is indeed found to provide a versatile formalism for describing the relationship between space and time in accordance with Einstein's relativistic principles, but nevertheless fails to provide more fundamental insights into the nature of time itself. In order to answer this question we begin by exploring the geometric properties of three-dimensional space that we model using Clifford geometric algebra, which is found to contain sufficient complexity to provide a natural description of spacetime. This description using Clifford algebra is found to provide a natural alternative to the Minkowski formulation as well as providing new insights into the nature of time. Our main result is that time is the scalar component of a Clifford space and can be viewed as an intrinsic geometric property of three-dimensional space without the need for the specific addition of a fourth dimension.

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Split quaternions and particles in (2+1)-space

Cited by 21 publications

References 29 publications

Geometrical Applications of Split Octonions

Geometrical Applications of Split Octonions

Split-Quaternion Analyticity and (2 + 1)-Electrodynamics

Time As a Geometric Property of Space

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