Universal coverings of orthogonal groups

Варламов, В. П.

doi:10.1007/s00006-004-0006-4

Cited by 26 publications

(57 citation statements)

References 62 publications

(111 reference statements)

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“…When N is odd, a simultaneous reflection along all axes commutes with SO(N ) and we can further simplify O(N ) ∼ = SO(N ) × Z 2 . The analogous relation for the groups P in ± (N ) is [41]…”

Section: Gauge Groupsmentioning

confidence: 98%

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Global Symmetries, Counterterms, and Duality in Chern-Simons Matter Theories with Orthogonal Gauge Groups

2018

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We study three-dimensional gauge theories based on orthogonal groups. Depending on the global form of the group these theories admit discrete θ-parameters, which control the weights in the sum over topologically distinct gauge bundles. We derive level-rank duality for these topological field theories. Our results may also be viewed as level-rank duality for SO(N ) K Chern-Simons theory in the presence of background fields for discrete global symmetries. In particular, we include the required counterterms and analysis of the anomalies. We couple our theories to charged matter and determine how these counterterms are shifted by integrating out massive fermions. By gauging discrete global symmetries we derive new boson-fermion dualities for vector matter, and present the phase diagram of theories with two-index tensor fermions, thus extending previous results for SO(N ) to other global forms of the gauge group. November, 2017a

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Section: Gauge Groupsmentioning

confidence: 98%

“…In this section we review aspects of these Chern-Simons theories. A discussion of the relevant group theory may be found in [38][39][40][41][42], while aspects of their bundles are described in [38,39].…”

Section: Groups Bundles and Lagrangiansmentioning

confidence: 99%

Global Symmetries, Counterterms, and Duality in Chern-Simons Matter Theories with Orthogonal Gauge Groups

2018

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“…In GA formulation no additional spacetime symmetry considerations are needed. As shown in the paper [11] the identity, inversion, reversion and Clifford conjugation operations in GA are isomorphic to group of four, which consists of identity operation, space P and time T reversals, and the combination PT. Thus in geometric algebra the symmetry operations P T PT 1, , , { } are automatically satisfied.…”

Section: Introductionmentioning

confidence: 99%

“…In GA the objects are multivectors of different grades that have geometric interpretation and can be simply manipulated including their transformations between same grade as well as different grade subspaces. The multivectors of GA satisfy a number of outermorphisms (or involutions) which automatically ensure symmetry properties of the spacetime, namely, P and T transformations of the space and time, and their combination PT [11]. Of all 64 irreducible Clifford algebras represented by 8-periodicity table [12], in optics and electrodynamics the two are the most important, namely, Cl 3,0 algebra which describes Euclidean 3D space and Cl 1,3 algebra which describes Minkowskian relativistic 4D spacetime.…”

Section: Introductionmentioning

confidence: 99%

Constitutive relations in optics in terms of geometric algebra

Dargys

2015

Optics Communications

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“…In our case, pure states of the form (3) correspond to charged states. At this point, the sign of charge is changed under action of the pseudoautomorphism A → A of the complex spinor structure (for more details see [24,25,26]). Following to analogy with the Lagrangian formalism, where neutral particles are described by real fields, we introduce vector states of the form…”

Section: Concrete Realization π(A)mentioning

confidence: 99%

Spinor Structure and Matter Spectrum

Варламов

2016

Int J Theor Phys

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Classification of relativistic wave equations is given on the ground of interlocking representations of the Lorentz group. A system of interlocking representations is associated with a system of eigenvector subspaces of the energy operator. Such a correspondence allows one to define matter spectrum, where the each level of this spectrum presents a some state of elementary particle. An elementary particle is understood as a superposition of state vectors in nonseparable Hilbert space. Classification of indecomposable systems of relativistic wave equations is produced for bosonic and fermionic fields on an equal footing (including Dirac and Maxwell equations). All these fields are equivalent levels of matter spectrum, which differ from each other by the value of mass and spin. It is shown that a spectrum of the energy operator, corresponding to a given matter level, is non-degenerate for the fields of type $(l,0)\oplus(0,l)$, where $l$ is a spin value, whereas for arbitrary spin chains we have degenerate spectrum. Energy spectra of the stability levels (electron and proton states) of the matter spectrum are studied in detail. It is shown that these stability levels have a nature of threshold scales of the fractal structure associated with the system of interlocking representations of the Lorentz group.Comment: 36 page

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Universal coverings of orthogonal groups

Cited by 26 publications

References 62 publications

Global Symmetries, Counterterms, and Duality in Chern-Simons Matter Theories with Orthogonal Gauge Groups

Global Symmetries, Counterterms, and Duality in Chern-Simons Matter Theories with Orthogonal Gauge Groups

Constitutive relations in optics in terms of geometric algebra

Spinor Structure and Matter Spectrum

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