:Gauge gravitation theory

The first gauge model of gravity was suggested by Ryoyu Utiyama (1916–1990) in 1956

{{cite journal

|last=Utiyama |first=R.

|year=1956

|title=Invariant theoretical interpretation of interaction

|journal=Physical Review

|volume=101 |page=1597

|doi=10.1103/PhysRev.101.1597

}}

just two years after birth of the gauge theory itself.

{{cite book

| first1=Milutin | last1=Blagojević

| first2=Friedrich W. | last2=Hehl

| year=2013

| title=Gauge Theories of Gravitation: A Reader with Commentaries

| publisher=World Scientific

| isbn=978-184-8167-26-1

}}

However, the initial attempts to construct the gauge theory of gravity by analogy with the gauge models of internal symmetries encountered a problem of treating general covariant transformations and establishing the gauge status of a pseudo-Riemannian metric (a tetrad field).

In order to overcome this drawback, representing tetrad fields as gauge fields of the translation group was attempted.

{{cite journal

|first1=F. |last1=Hehl |first2=J. |last2=McCrea

|first3=E. |last3=Mielke |first4=Y. |last4=Ne'eman

|year=1995

|title=Metric-affine gauge theory of gravity: Field equations, Noether identities, world spinors, and breaking of dilaton invariance

|journal=Physics Reports

|volume=258 |page=1

|doi=10.1016/0370-1573(94)00111-F

|arxiv=gr-qc/9402012}}

Infinitesimal generators of general covariant transformations were considered as those of the translation gauge group, and a tetrad (coframe) field was identified with the translation part of an affine connection on a world manifold $X$. Any such connection is a sum $K=\backslash Gamma\; +\; \backslash Theta$ of a linear world connection $\backslash Gamma$ and a soldering form $\backslash Theta=\; \backslash Theta\_\backslash mu^a\; dx^\backslash mu\backslash otimes\backslash vartheta\_a$ where $\backslash vartheta\_a=\backslash vartheta\_a^\backslash lambda\backslash partial\_\backslash lambda$ is a non-holonomic frame. For instance, if $K$ is the Cartan connection, then $\backslash Theta=\backslash theta=dx^\backslash mu\backslash otimes\backslash partial\_\backslash mu$ is the canonical soldering form on $X$. There are different physical interpretations of the translation part $\backslash Theta$ of affine connections. In gauge theory of dislocations, a field $\backslash Theta$ describes a distortion.

{{cite journal

|last=Malyshev |first=C.

|year=2000

|title=The dislocation stress functions from the double curl {{mvar|T}}(3)-gauge equations: Linearity and look beyond

|journal=Annals of Physics

|volume=286 |page=249

|doi=10.1006/aphy.2000.6088

|arxiv=cond-mat/9901316

}}

At the same time, given a linear frame $\backslash vartheta\_a$, the decomposition $\backslash theta=\backslash vartheta^a\backslash otimes\backslash vartheta\_a$ motivates many authors to treat a coframe $\backslash vartheta^a$ as a translation gauge field.

{{cite book

|last=Blagojević |first=M.

|year=2002

|title=Gravitation and Gauge Symmetries

|place=Bristol, UK

|publisher=IOP Publishing

}}

Difficulties of constructing gauge gravitation theory by analogy with the Yang–Mills one result from the gauge transformations in these theories belonging to different classes. In the case of internal symmetries, the gauge transformations are just vertical automorphisms of a principal bundle $P\backslash to\; X$ leaving its base $X$ fixed. On the other hand, gravitation theory is built on the principal bundle $FX$ of the tangent frames to $X$. It belongs to the category of natural bundles $T\backslash to\; X$ for which diffeomorphisms of the base $X$ canonically give rise to automorphisms of {{mvar|T}}.

{{cite book

|first1=I. |last1=Kolář

|first2=P.W. |last2=Michor

|first3=J. |last3=Slovák

|year=1993

|title=Natural Operations in Differential Geometry

|publisher=Springer-Verlag

|place=Berlin & Heidelberg

}}

These automorphisms are called general covariant transformations. General covariant transformations are sufficient in order to restate Einstein's general relativity and metric-affine gravitation theory as the gauge ones.

In terms of gauge theory on natural bundles, gauge fields are linear connections on a world manifold $X$, defined as principal connections on the linear frame bundle $FX$, and a metric (tetrad) gravitational field plays the role of a Higgs field responsible for spontaneous symmetry breaking of general covariant transformations.

{{cite journal

|author1-link=Dmitri Ivanenko |first1=D. |last1=Ivanenko

|author2-link=Gennadi Sardanashvily |first2=G. |last2=Sardanashvily

|year=1983

|title=The gauge treatment of gravity

|journal=Physics Reports

|volume=94 |page=1

|doi=10.1016/0370-1573(83)90046-7

}}

Spontaneous symmetry breaking is a quantum effect when the vacuum is not invariant under the transformation group. In classical gauge theory, spontaneous symmetry breaking occurs if the structure group $G$ of a principal bundle $P\backslash to\; X$ is reducible to a closed subgroup $H$, i.e., there exists a principal subbundle of $P$ with the structure group $H$.

{{cite journal

|last1=Nikolova |first1=L.

|last2=Rizov |first2=V.

|year=1984

|title=Geometrical approach to the reduction of gauge theories with spontaneous broken symmetries

|journal=Reports on Mathematical Physics

|volume=20 |page=287

|doi=10.1016/0034-4877(84)90039-9

}}

By virtue of the well-known theorem, there exists one-to-one correspondence between the reduced principal subbundles of $P$ with the structure group $H$ and the global sections of the quotient bundle {{math|P / H → X}}. These sections are treated as classical Higgs fields.

The idea of the pseudo-Riemannian metric as a Higgs field appeared while constructing non-linear (induced) representations of the general linear group {{math|GL(4, R)}}, of which the Lorentz group is a Cartan subgroup.

{{cite journal

|first=M. |last=Leclerc

|year=2006

|title=The Higgs sector of gravitational gauge theories

|journal=Annals of Physics

|volume=321 |page=708

|doi=10.1016/j.aop.2005.08.009

|arxiv=gr-qc/0502005

}}

The geometric equivalence principle postulating the existence of a reference frame in which Lorentz invariants are defined on the whole world manifold is the theoretical justification for the reduction of the structure group {{math|GL(4, R)}} of the linear frame bundle {{math|FX}} to the Lorentz group. Then the very definition of a pseudo-Riemannian metric on a manifold $X$ as a global section of the quotient bundle {{math|FX / O(1, 3) → X}} leads to its physical interpretation as a Higgs field. The physical reason for world symmetry breaking is the existence of Dirac fermion matter, whose symmetry group is the universal two-sheeted covering {{math|SL(2, C)}} of the restricted Lorentz group, {{math|SO{{sup|+}}(1, 3)}}.

{{cite book

|author1-link=Gennadi Sardanashvily |first1=G. |last1=Sardanashvily

|first2=O. |last2=Zakharov

|year=1992

|title=Gauge Gravitation Theory

|place=Singapore

|publisher=World Scientific

}}

{{cmn|colwidth=30em|

• Ashtekar variables
• Metric-affine gravitation theory
• Einstein–Cartan theory
• Spontaneous symmetry breaking
• Teleparallelism
• Reduction of the structure group
• Higgs field (classical)
• General covariant transformations
• Equivalence principle (geometric)
• Affine gauge theory
• Classical unified field theories}}

{{reflist|25em}}

• {{cite journal

|first=I. |last=Kirsch

|year=2005

|title=A Higgs mechanism for gravity

|journal=Phys. Rev. D

|volume=72 |page=024001

|arxiv=hep-th/0503024

}}

• {{cite journal

|last=Sardanashvily |first=G. |author-link=Gennadi Sardanashvily

|year=2011

|title=Classical gauge gravitation theory

|journal=Int. J. Geom. Methods Mod. Phys.

|volume=8 |pages=1869–1895

|arxiv=1110.1176

}}

• {{cite journal

|first=Yu. |last=Obukhov

|year=2006

|title=Poincaré gauge gravity: Selected topics

|journal=Int. J. Geom. Methods Mod. Phys.

|volume=3 |pages=95–138

|arxiv=gr-qc/0601090

}}

Category:Gauge theories

Category:Theories of gravity