Principal bundle, parabolic bundle, and holomorphic connection

1991 ◽

Vol 06 (04) ◽

pp. 577-598 ◽

Cited By ~ 4

Author(s):

A.G. SAVINKOV ◽

A.B. RYZHOV

Keyword(s):

Green's Functions ◽

Principal Bundle ◽

Fibre Bundle ◽

Green’S Functions ◽

Wave Functions ◽

Total Space ◽

Dirac Monopole ◽

Hidden Symmetries ◽

Scattering Wave ◽

A Charge

The scattering wave functions and Green’s functions were found in a total space of a Dirac monopole principal bundle. Also, hidden symmetries of a charge-Dirac monopole system and those joining the states relating to different topological charges n=2eg were found.

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The Gauge Group of a Principal Bundle

Graduate Texts in Mathematics - Fibre Bundles ◽

10.1007/978-1-4757-2261-1_7 ◽

1994 ◽

pp. 79-86

Author(s):

Dale Husemoller

Keyword(s):

Gauge Group ◽

Principal Bundle

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Deformation quantization of principal bundles

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887816300105 ◽

2016 ◽

Vol 13 (08) ◽

pp. 1630010

Author(s):

Paolo Aschieri

Keyword(s):

Quantum Group ◽

Deformation Quantization ◽

Principal Bundle ◽

Base Space ◽

Structure Group ◽

Galois Extensions ◽

Principal Bundles ◽

Group Of Automorphisms ◽

Drinfeld Twist

We outline how Drinfeld twist deformation techniques can be applied to the deformation quantization of principal bundles into noncommutative principal bundles and, more in general, to the deformation of Hopf–Galois extensions. First, we twist deform the structure group in a quantum group, and this leads to a deformation of the fibers of the principal bundle. Next, we twist deform a subgroup of the group of automorphisms of the principal bundle, and this leads to a noncommutative base space. Considering both deformations, we obtain noncommutative principal bundles with noncommutative fiber and base space as well.

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Poisson Principal Bundles

Symmetry Integrability and Geometry Methods and Applications ◽

10.3842/sigma.2021.006 ◽

2021 ◽

Author(s):

Shahn Majid ◽

◽

Liam Williams ◽

Keyword(s):

Quantum Group ◽

Lie Group ◽

Poisson Structure ◽

Differential Calculus ◽

Principal Bundle ◽

Poisson Manifold ◽

Spin Connection ◽

Poisson Geometry ◽

Hopf Fibration ◽

Principal Bundles

We semiclassicalise the theory of quantum group principal bundles to the level of Poisson geometry. The total space X is a Poisson manifold with Poisson-compatible contravariant connection, the fibre is a Poisson-Lie group in the sense of Drinfeld with bicovariant Poisson-compatible contravariant connection, and the base has an inherited Poisson structure and Poisson-compatible contravariant connection. The latter are known to be the semiclassical data for a quantum differential calculus. The theory is illustrated by the Poisson level of the q-Hopf fibration on the standard q-sphere. We also construct the Poisson level of the spin connection on a principal bundle.

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The Palais–Smale conditions for the Yang–Mills functional

Proceedings of the Royal Society of Edinburgh Section A Mathematics ◽

10.1017/s030821050001461x ◽

1988 ◽

Vol 108 (3-4) ◽

pp. 189-200

Author(s):

D. R. Wilkins

Keyword(s):

Riemannian Manifold ◽

Principal Bundle ◽

Compact Riemannian Manifold ◽

Hilbert Manifold ◽

Yang Mills ◽

Palais Smale Condition ◽

Dimension 2

SynopsisWe consider the Yang–Mills functional denned on connections on a principal bundle over a compact Riemannian manifold of dimension 2 or 3. It is shown that if we consider the Yang–Mills functional as being defined on an appropriate Hilbert manifold of orbits of connections under the action of the group of principal bundle automorphisms, then the functional satisfies the Palais–Smale condition.

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Connections on a Principal Bundle

Introductory Lectures on Equivariant Cohomology ◽

10.2307/j.ctvrdf1gz.22 ◽

2020 ◽

pp. 127-134

Keyword(s):

Principal Bundle

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Basic Forms

Introductory Lectures on Equivariant Cohomology ◽

10.23943/princeton/9780691191751.003.0012 ◽

2020 ◽

pp. 97-102

Author(s):

Loring W. Tu

Keyword(s):

Lie Group ◽

Principal Bundle ◽

Differential Forms ◽

Total Space ◽

Lie Derivative ◽

Connected Lie Group

This chapter describes basic forms. On a principal bundle π‎: P → M, the differential forms on P that are pullbacks of forms ω‎ on the base M are called basic forms. The chapter characterizes basic forms in terms of the Lie derivative and interior multiplication. It shows that basic forms on a principal bundle are invariant and horizontal. To understand basic forms better, the chapter considers a simple example. The plane ℝ2 may be viewed as the total space of a principal ℝ-bundle. A connected Lie group is generated by any neighborhood of the identity. This example shows the necessity of the connectedness hypothesis.

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Homotopy Quotients and Equivariant Cohomology

Introductory Lectures on Equivariant Cohomology ◽

10.23943/princeton/9780691191751.003.0004 ◽

2020 ◽

pp. 29-38

Author(s):

Loring W. Tu

Keyword(s):

Topological Group ◽

Fiber Bundle ◽

Equivariant Cohomology ◽

Principal Bundle ◽

Total Space

This chapter investigates two candidates for equivariant cohomology and explains why it settles on the Borel construction, also called Cartan's mixing construction. Let G be a topological group and M a left G-space. The Borel construction mixes the weakly contractible total space of a principal bundle with the G-space M to produce a homotopy quotient of M. Equivariant cohomology is the cohomology of the homotopy quotient. More generally, given a G-space M, Cartan's mixing construction turns a principal bundle with fiber G into a fiber bundle with fiber M. Cartan's mixing construction fits into the Cartan's mixing diagram, a powerful tool for dealing with equivariant cohomology.

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