NTMF060 - Geometrical Methods of Theoretical Physics II

Annotation:

Hodge theory (Hodge decomposition, de Rham-Laplace operator, harmonics). Topological methods (Cohomology a homology groups, homotopy, fundamental group, homotopy equivalence, Poincare lemma). Riemann geometry in terms of forms (Cartan structure equations, calculation of the curvature). Geometry of Lie groups and algebras (geometric structures on Lie groups, Lie algebra, the action of Lie group on a manifold, vector representations). Fibre bundles (vector bundles, covariant derivative). Geometry of gauge fields (inner degrees of freedom, gauge symmetry, the action and field equations). Characteristic classes (invariant symmetric polynomials, Chern-Weil theorem, characteristic classes, Euler form). Two-component spinors (relation between spinors and vectors, soldering form, physical fields in terms of spinors).

Knowledge of the differential geometry at the level of the course NTMF059 is assumed.

Information about lectures in spring term 2022:

The course is scheduled on Wednesdays at 14:00–16:20 in lecture room T1.

The lectures are given in English.

Lectures are given in person. They are also recorded and available for enrolled students. Students have access also to lectures from 2021 in Czech.

Syllabus:

Hodge theory: Scalar product on forms, Hodge dual, coderivative, de Rham-Laplace and Beltrami-Laplace operators. Hodge decomposition, potential and copotential, harmonics, cohomology.
Topological methods: Cohomology a homology groups, homotopy, fundamental group, homotopy equivalence, homotopy operator, contraction, Poincare lemma.
Riemann geometry in terms of forms: Maxwell theory. Othonormal frames, Cartan structure equations, Ricci coefficients. Bianchi identities. Calculation of the curvature, example - Vaidya metric.
Geometry of Lie groups and algebras: Lie groups, construction of Lie algebra, exponential mapping, Killing metric, structure constants. Bi-invariant metric, measure, covariant derivative. Adjoint representations. The action of Lie group on a manifold, flows and their generators. Representations on vector spaces.
Fibre bundles: Abstract fibre bundles. Vector bundles and their geometry, covariant derivative, vector potential and curvature. Objects on the gauge-algebra bundle.
Geometry of gauge fields: Inner degrees of freedom and their description in terms of vector bundles. Gauge symmetry. Gauge group and gauge algebra bundles. Gauge and Yang-Mills fields. The action and field equations. Electromagnetic and charged fields.
Characteristic classes: Invariant symmetric polynomials in curvature, Chern-Weil theorem, characteristic classes, Chern class and character, Pontrjagin class, Euler form, integral quantities.
Two-component spinors: Space of spinors, antisymmetric metric, soldering form. Relation between spinors and vectors. Geometric quantities and physical fields in terms of spinors. Electromagnetic field and curvature.

Studijní texty:

Vedle literatury uvedené níže jsou k dispozici texty speciálně k přednášce NTMF059:

O. Kowalski: Základy Riemannovy geometrie, skripta, Karolinum, Praha 1995
P. Krtouš: Geometrické metody ve fyzice, studijní text, WWWhttp://utf.mff.cuni.cz/vyuka/NTMF059/GeometrickeMetody/, 2006-2014

Literature:

C. von Westenholz: Differential Forms in Mathematical Physics, North-Holland, 1978.
M. Fecko: Differential Geometry and Lie Groups for Physicists, Cambridge Univ. Press, 2011.
T. Frankel: The Geometry of Physics - An Introduction, Cambridge Univ. Press, 1999.
M. Nakahara: Geometry, Topology and Physics, Taylor&Francis, 2003.
Ch. Nash, S. Sen: Topology and Geometry for Physicists, Dover Publ., 2011.
Ch. J. Isham: Moddern Differential Geometry For Physicists, World Scientific, 1989.
E. W. Mielke: Geometrodynamics of Gauge Fields, Springer, 2017.
R. Penrose a W. Rindler: Spinors and space-time, Cambridge Univ. Press, 1999.
P. O'Donnell: 2-Spinors in General Relativity, World Scientific, 2003.
C. W. Misner, K. S. Thorne a J. A. Wheeler: Gravitation, Freedman, 1973.
S. Kobayashi a K. Nomizu: Foundations of Differential Geometry I, Interscience Publishers, 1963.
M. Spivak: A Comprehensive Introduction to Differential Geometry, Publish or Perish Press, 1970-1979.
V. I. Arnold: Mathematical methods of classical mechanics, Graduate Texts in Math. No. 60, Springer-Verlag, 1978.
R. Abraham a J. E. Marsden: Foundations of Mechanics, Addison-Wesley, 1985.