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Affine gauge theory is classical gauge theory where gauge fields are affine connections on the tangent bundle over a smooth manifold X. For instance, these are gauge theory of dislocations in continuous media when X=3, the generalization of metric-affine gravitation theory when X is a world manifold and, in particular, gauge theory of the fifth force.


Affine tangent bundle

Being a vector bundle, the tangent bundle TX of an n-dimensional manifold X admits a natural structure of an affine bundle ATX, called the affine tangent bundle, possessing bundle atlases with affine transition functions. It is associated to a principal bundle AFX of affine frames in tangent space over X, whose structure group is a general affine group GA(n,).

The tangent bundle TX is associated to a principal linear frame bundle FX, whose structure group is a general linear group GL(n,). This is a subgroup of GA(n,) so that the latter is a semidirect product of GL(n,) and a group Tn of translations.

There is the canonical imbedding of FX to AFX onto a reduced principal subbundle which corresponds to the canonical structure of a vector bundle TX as the affine one.

Given linear bundle coordinates

(xμ,x˙μ),x˙'μ=x'μxνx˙ν,(1)

on the tangent bundle TX, the affine tangent bundle can be provided with affine bundle coordinates

(xμ,x~μ=x˙μ+aμ(xα)),x~'μ=x'μxνx~ν+bμ(xα).(2)

and, in particular, with the linear coordinates (1).


Affine gauge fields

The affine tangent bundle ATX admits an affine connection A which is associated to a principal connection on an affine frame bundle AFX. In affine gauge theory, it is treated as an affine gauge field.

Given the linear bundle coordinates (1) on ATX=TX, an affine connection A is represented by a connection tangent-valued form

A=dxλ[λ+(Γλμν(xα)x˙ν+σλμ(xα))˙μ].(3)

This affine connection defines a unique linear connection

Γ=dxλ[λ+Γλμν(xα)x˙ν˙μ](4)

on TX, which is associated to a principal connection on FX.

Conversely, every linear connection Γ (4) on TXX is extended to the affine one AΓ on ATX which is given by the same expression (4) as Γ with respect to the bundle coordinates (1) on ATX=TX, but it takes a form

AΓ=dxλ[λ+(Γλμν(xα)x~ν+sμ(xα))~μ],sμ=Γλμνaν+λaμ,

relative to the affine coordinates (2).

Then any affine connection A (3) on ATXX is represented by a sum

A=AΓ+σ(5)

of the extended linear connection AΓ and a basic soldering form

σ=σλμ(xα)dxλμ(6)

on TX, where ˙μ=μ due to the canonical isomorphism VATX=ATX×XTX of the vertical tangent bundle VATX of ATX.

Relative to the linear coordinates (1), the sum (5) is brought into a sum A=Γ+σ of a linear connection Γ and the soldering form σ (6). In this case, the soldering form σ (6) often is treated as a translation gauge field, though it is not a connection.

Let us note that a true translation gauge field (i.e., an affine connection which yields a flat linear connection on TX) is well defined only on a parallelizable manifold X.

Gauge theory of dislocations

In field theory, one meets a problem of physical interpretation of translation gauge fields because there are no fields subject to gauge translations u(x)u(x)+a(x). At the same time, one observes such a field in gauge theory of dislocations in continuous media because, in the presence of dislocations, displacement vectors uk, k=1,2,3, of small deformations are determined only with accuracy to gauge translations ukuk+ak(x).

In this case, let X=3, and let an affine connection take a form

A=dxi(i+Aij(xk)~j)

with respect to the affine bundle coordinates (2). This is a translation gauge field whose coefficients Alj describe plastic distortion, covariant derivatives Djui=juiAji coincide with elastic distortion, and a strength Fjik=jAikiAjk is a dislocation density.

Equations of gauge theory of dislocations are derived from a gauge invariant Lagrangian density

L(σ)=μDiukDiuk+λ2(Diui)2ϵFkijFkij,

where μ and λ are the Lame parameters of isotropic media. These equations however are not independent since a displacement field uk(x) can be removed by gauge translations and, thereby, it fails to be a dynamic variable.


Gauge theory of the fifth force

In gauge gravitation theory on a world manifold X, one can consider an affine, but not linear connection on the tangent bundle TX of X. Given bundle coordinates (1) on TX, it takes the form (3) where the linear connection Γ (4) and the basic soldering form σ (6) are considered as independent variables.

As was mentioned above, the soldering form σ (6) often is treated as a translation gauge field, though it is not a connection. On another side, one mistakenly identifies σ with a tetrad field. However, these are different mathematical object because a soldering form is a section of the tensor bundle TXT*X, whereas a tetrad field is a local section of a Lorentz reduced subbundle of a frame bundle FX.

In the spirit of the above mentioned gauge theory of dislocations, it has been suggested that a soldering field σ can describe sui generi deformations of a world manifold X which are given by a bundle morphism

s:TXλλ(θ+σ)=(δλν+σλν)νTX,

where θ=dxμμ is a tautological one-form.

Then one considers metric-affine gravitation theory (g,Γ) on a deformed world manifold as that with a deformed pseudo-Riemannian metric g~μν=sαμsβνgαβ when a Lagrangian of a soldering field σ takes a form

L(σ)=12[a1TμνμTανα+a2TμναTμνα+a3TμναTνμα+a4ϵμναβTγμγTβναμσμνσνμ+λσμμσνν]g,

where ϵμναβ is the Levi-Civita symbol, and

Tανμ=DνσαμDμσαν

is the torsion of a linear connection Γ with respect to a soldering form σ.

In particular, let us consider this gauge model in the case of small gravitational and soldering fields whose matter source is a point mass. Then one comes to a modified Newtonian potential of the fifth force type.


References

  • A. Kadic, D. Edelen, A Gauge Theory of Dislocations and Disclinations, Lecture Notes in Physics 174 (Springer, New York, 1983), ISBN 3-540-11977-9
  • G. Sardanashvily, O. Zakharov, Gauge Gravitation Theory (World Scientific, Singapore, 1992), ISBN 981-02-0799-9
  • C. Malyshev, The dislocation stress functions from the double curl T(3)-gauge equations: Linearity and look beyond, Annals of Physics 286 (2000) 249.


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See also