2019
DOI: 10.1016/j.physletb.2019.03.029
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Noncommutative spaces of worldlines

Abstract: The space of time-like geodesics on Minkowski spacetime is constructed as a coset space of the Poincaré group in (3+1) dimensions with respect to the stabilizer of a worldline. When this homogeneous space is endowed with a Poisson homogeneous structure compatible with a given Poisson-Lie Poincaré group, the quantization of this Poisson bracket gives rise to a noncommutative space of worldlines with quantum group invariance. As an oustanding example, the Poisson homogeneous space of worldlines coming from the κ… Show more

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Cited by 21 publications
(68 citation statements)
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“…Indeed, the consequences of making use of the κ-(A)dS noncommutative spacetime (2) from different quantum gravity perspectives have to be explored promptly by following similar approaches to the ones used so far for the κ-Minkowski spacetime (see, for instance, [22]- [39]). Work on this line is currently in progress and will be presented elsewhere.…”
Section: Discussionmentioning
confidence: 99%
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“…Indeed, the consequences of making use of the κ-(A)dS noncommutative spacetime (2) from different quantum gravity perspectives have to be explored promptly by following similar approaches to the ones used so far for the κ-Minkowski spacetime (see, for instance, [22]- [39]). Work on this line is currently in progress and will be presented elsewhere.…”
Section: Discussionmentioning
confidence: 99%
“…Moreover, it is straightforward to check that the Poisson brackets (36) arise in the Sklyanin bracket just from the J 1 ∧ J 2 term of the r-matrix (30). This explains why the Poisson algebra (39) is naturally linked to the semiclassical limit of the quantum SU(2) subgroup of the κ-(A)dS deformation, albeit realized on the 3-space coordinates. In this respect, we recall that the su(2) subalgebra generated by {J 1 , J 2 , J 3 } becomes a quantum su(2) subalgebra when the full quantum deformation is constructed [45], a fact that can already be envisaged from the cocommutator (34) where the su(2) generators define a sub-Lie bialgebra.…”
Section: The κ-(A)ds Noncommutative Spacetimementioning
confidence: 99%
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“…Among other issues and within the vast literature, let us mention that κ-Minkowski space along with the κ-Poincaré algebra have been studied in relation to noncommutative differential calculi [72,73], wave propagation on noncommutative spacetimes [74], deformed or doubly special relativity at the Planck scale [75][76][77][78][79][80], noncommutative field theory [81][82][83], representation theory on Hilbert spaces [84,85], generalized κ-Minkowski spacetimes through twisted κ-Poincaré deformations [86,87], deformed dispersion relations [88][89][90], curved momentum spaces [91][92][93][94][95], relative locality phenomena [96], star products [97], deformed phase spaces [98], noncommutative spaces of worldlines [99,100] and light cones [101] (in all cases see the references therein).…”
Section: Quantum Groups and Noncommutative Spacesmentioning
confidence: 99%