Rose–Vinet equation of state

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A gauge group is a group of gauge symmetries of the Yang – Mills gauge theory of principal connections on a principal bundle. Given a principal bundle PX with a structure Lie group G, a gauge group is defined to be a group of its vertical automorphisms. This group is isomorphic to the group G(X) of global sections of the associated group bundle P~X whose typical fiber is a group G which acts on itself by the adjoint representation. The unit element of G(X) is a constant unit-valued section g(x)=1 of P~X.

At the same time, gauge gravitation theory exemplifies field theory on a principal frame bundle whose gauge symmetries are general covariant transformations which are not elements of a gauge group.

It should be emphasized that, in the physical literature on gauge theory, a structure group of a principal bundle often is called the gauge group.

In quantum gauge theory, one considers a normal subgroup G0(X) of a gauge group G(X) which is the stabilizer

G0(X)={g(x)G(X):g(x0)=1P~x0}

of some point 1P~x0 of a group bundle P~X. It is called the pointed gauge group. This group acts freely on a space of principal connections. Obviously, G(X)/G0(X)=G. One also introduces the effective gauge group G(X)=G(X)/Z where Z is the center of a gauge group G(X). This group G(X) acts freely on a space of irreducible principal connections.

If a structure group G is a complex semisimple matrix group, the Sobolev completion Gk(X) of a gauge group G(X) can be introduced. It is a Lie group. A key point is that the action of Gk(X) on a Sobolev completion Ak of a space of principal connections is smooth, and that an orbit space Ak/Gk(X) is a Hilbert space. It is a configuration space of quantum gauge theory.

References

  • Mitter, P., Viallet, C., On the bundle of connections and the gauge orbit manifold in Yang – Mills theory, Commun. Math. Phys. 79 (1981) 457.
  • Marathe, K., Martucci, G., The Mathematical Foundarions of Gauge Theory (North Holland, 1992) ISBN 0-444-89708-9.
  • Mangiarotti, L., Sardanashvily, G., Connections in Classical and Quantum Field Theory (World Scientific, 2000) ISBN 981-02-2013-8

See also