Newton equation for canonical, Lie-algebraic, and quadratic deformation of classical space

Daszkiewicz, Marcin; Walczyk, Cezary J.

doi:10.1103/physrevd.77.105008

Cited by 36 publications

(59 citation statements)

References 54 publications

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“…This transformation can be a generic function of momenta, but linear in coordinates (for discussions on noncommutative classical mechanics see e.g. [44]). …”

Section: A Deformed Heisenberg Algebrasmentioning

confidence: 99%

Scalar field theory on noncommutative Snyder spacetime

2010

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We construct a scalar field theory on the Snyder noncommutative space-time. The symmetry underlying the Snyder geometry is deformed at the co-algebraic level only, while its Poincaré algebra is undeformed. The Lorentz sector is undeformed at both the algebraic and co-algebraic level, but the coproduct for momenta (defining the star product) is non-coassociative. The Snyder-deformed Poincaré group is described by a non-coassociative Hopf algebra. The definition of the interacting theory in terms of a nonassociative star product is thus questionable. We avoid the nonassociativity by the use of a space-time picture based on the concept of the realization of a noncommutative geometry. The two main results we obtain are (i) the generic (namely, for any realization) construction of the co-algebraic sector underlying the Snyder geometry and (ii) the definition of a nonambiguous self-interacting scalar field theory on this space-time. The first-order correction terms of the corresponding Lagrangian are explicitly computed. The possibility to derive Noether charges for the Snyder space-time is also discussed.

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“…This transformation can be a generic function of momenta, but linear in coordinates (for discussions on noncommutative classical mechanics see e.g. [44]). …”

Section: A Deformed Heisenberg Algebrasmentioning

confidence: 99%

Scalar field theory on noncommutative Snyder spacetime

2010

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“…There has been a large amount of literature on noncommutative quantum mechanics (NCQM) [3] and noncommutative field theory (NCFT) [4] as well. However, we notice that the research on noncommutative classical mechanics 1 (NCCM) [5,6,7], if comparing with that of NCQM and NCFT, is so little. Probably the NCCM is not so attractive as the NCQM and NCFT; nevertheless, the Doubly Special Relativity [7] has been intriguing.…”

Section: Introductionmentioning

confidence: 95%

Classical mechanics on noncommutative space with Lie-algebraic structure

2011

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a b s t r a c tWe investigate the kinetics of a nonrelativistic particle interacting with a constant external force on a Lie-algebraic noncommutative space. The structure constants of a Lie algebra, also called noncommutative parameters, are constrained in general due to some algebraic properties, such as the antisymmetry and Jacobi identity. Through solving the constraint equations the structure constants satisfy, we obtain two new sorts of algebraic structures, each of which corresponds to one type of noncommutative spaces. Based on such types of noncommutative spaces as the starting point, we analyze the classical motion of the particle interacting with a constant external force by means of the Hamiltonian formalism on a Poisson manifold. Our results not only include that of a recent work as our special cases, but also provide new trajectories of motion governed mainly by marvelous extra forces. The extra forces with the unimaginable t _ xÀ; _ ðxxÞ-, and € ðxxÞ-dependence besides with the usual t-, x-, and _x-dependence, originating from a variety of noncommutativity between different spatial coordinates and between spatial coordinates and momenta as well, deform greatly the particle's ordinary trajectories we are quite familiar with on the Euclidean (commutative) space.

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“…In both cases, the angle α is constant in time. Moreover, in the case of canonically deformed phase space it has been proved in [9] that for Hamiltonian function of the form…”

Section: Introductionmentioning

confidence: 99%