Seminar talk, 18 May 2022: Difference between revisions
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| title = Noncommutative quantum mechanical systems associated with Lie algebras | | title = Noncommutative quantum mechanical systems associated with Lie algebras | ||
| abstract = We consider quantum mechanics on the noncommutative spaces characterized by the commutation relations | | abstract = We consider quantum mechanics on the noncommutative spaces characterized by the commutation relations | ||
<math> [x_a, x_b] \ =\ i\theta f_{abc} x_c\,,</math> | <math> [x_a, x_b] \ =\ i\theta f_{abc} x_c\,,</math> | ||
where <math>f_{abc}</math> are the structure constants of a Lie algebra. We note that this problem can be reformulated as an ordinary quantum problem in a commuting {\it momentum} space. The coordinates are then represented as linear differential operators <math>\hat x_a = -i \hat D_a = -iR_{ab} (p)\, \partial /\partial p_b </math>. Generically, the matrix <math>R_{ab}(p)</math> represents a certain infinite series over the deformation parameter <math>\theta</math>: <math>R_{ab} = \delta_{ab} + \ldots</math>. The deformed Hamiltonian, <math>\hat H \ =\ - \frac 12 \hat D_a^2\,, </math> describes the motion along the corresponding group manifolds with the characteristic size of order <math>\theta^{-1}</math>. Their metrics are also expressed into certain infinite series in <math>\theta</math>. | where <math>f_{abc}</math> are the structure constants of a Lie algebra. We note that this problem can be reformulated as an ordinary quantum problem in a commuting {\it momentum} space. The coordinates are then represented as linear differential operators <math>\hat x_a = -i \hat D_a = -iR_{ab} (p)\, \partial /\partial p_b </math>. Generically, the matrix <math>R_{ab}(p)</math> represents a certain infinite series over the deformation parameter <math>\theta</math>: <math>R_{ab} = \delta_{ab} + \ldots</math>. The deformed Hamiltonian, <math>\hat H \ =\ - \frac 12 \hat D_a^2\,, </math> describes the motion along the corresponding group manifolds with the characteristic size of order <math>\theta^{-1}</math>. Their metrics are also expressed into certain infinite series in <math>\theta</math>. | ||
Revision as of 12:54, 13 May 2022
Speaker: Andrei Smilga
Title: Noncommutative quantum mechanical systems associated with Lie algebras
Abstract:
We consider quantum mechanics on the noncommutative spaces characterized by the commutation relations
![{\displaystyle [x_{a},x_{b}]\ =\ i\theta f_{abc}x_{c}\,,}](https://wikimedia.org/api/rest_v1/media/math/render/svg/08f0b215d1acbaf58bc735050f16371b09e6dba1)
where are the structure constants of a Lie algebra. We note that this problem can be reformulated as an ordinary quantum problem in a commuting {\it momentum} space. The coordinates are then represented as linear differential operators . Generically, the matrix represents a certain infinite series over the deformation parameter : . The deformed Hamiltonian, describes the motion along the corresponding group manifolds with the characteristic size of order . Their metrics are also expressed into certain infinite series in .
For the algebras and , it has been possible to represent the operators in a simple finite form. A byproduct of our study are new nonstandard formulas for the metrics on and on .
References:
arXiv:2204.08705
