A Weyl-Cartan space-time model based on the gauge principle

Baburova, O. V.; Zhukovsky, V. Ch.; Frolov, B. N.

doi:10.1007/s11232-008-0117-5

Cited by 20 publications

(13 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This difficulty was overcome in a new variant of the Poincaré-gauge gravitation theory [4,5] and a recently developed Poincaré-Weyl-gauge gravitation theory [6,7], where the angular momentum The theory is developed on the basis of the Noether theorems allowing gauge fields dynamically realizing the laws of conservation of energy-momentum, total rotational moment (orbital and spin), and dilatation charge to be introduced. The dilatation charge is due to the invariance of the theory with respect to tension and compression of spacetime.…”

mentioning

confidence: 99%

“…In [6,7], discussed is the case where a spinor field plays the role of external one. The Lagrange density of interaction with the gauge field of the Poincaré-Weyl group is written as , .…”

mentioning

confidence: 99%

“…Let us calculate the foregoing additional, as compared with standard GRT, interaction in the Lagrangian [7]. Calculations for the spinor field of the energy-momentum tensor result in…”

mentioning

confidence: 99%

“…In the absence of action upon the orbital moment, the orbit plane will take up a constant position in space. Under fairly slow action of the Lorentz gauge field upon the orbital moment, precession of the orbit will take place [7]. This phenomenon will be perceived as a change in diamagnetic properties of matter, therefore, we can assume that this effect can be used for detecting gravitational and torsional waves.…”

mentioning

confidence: 99%

See 3 more Smart Citations

The “Gravity Probe B” experiment, interaction between the orbital moment and gauge field, and a gravidiamagnetic effect

Baburova

Frolov

2011

Russ Phys J

Self Cite

View full text Add to dashboard Cite

At the present time, the "Gravity Probe B" (GP-B) experiment is being performed on the orbit aimed at investigation into features of motion of a rotating probe body (gyro) in the Earth's gravitational field. The results of measurements are under processing and will be compared with the predictions of GRT and its various generalizations.It is well known that classical experiments confirm GRT accurate to 0.3%. Therefore, there is reason to hope that the foregoing experiment will identify departures from GRT.In [1], it is proposed to treat possible variations of the experiment results from the GRT predictions as the presence of torsion of spacetime in the above experiment. In this work, it is assumed that a gyro could respond to torsion if a rotating planet-type body was able to produce spacetime torsion, hence the experiments with a gyro like the above GRB can be the best means for determination of the most adequate of all possible unconventional gravitation theories allowing for torsion.A nonconventional theory is necessitated by the fact that it is assumed in the conventional Poincaré -gauge gravitation theory [2, 3] that the orbital angular momentum cannot be a source of field due to the absence of translational invariance of the field equations arising in this case. This was discussed in detail in the well-known review [3]. In [1], this opinion was cited as a common folklore in modern theory of gravitational field. This difficulty was overcome in a new variant of the Poincaré-gauge gravitation theory [4, 5] and a recently developed Poincaré-Weyl-gauge gravitation theory [6, 7], where the angular momentum a m M along with the spin moment a m S occur as a source of gravitational field, including the torsional field, without violation of translational invariance of the field equations.The theory is developed on the basis of the Noether theorems allowing gauge fields dynamically realizing the laws of conservation of energy-momentum, total rotational moment (orbital and spin), and dilatation charge to be introduced. The dilatation charge is due to the invariance of the theory with respect to tension and compression of spacetime. As a result, the theory necessitates the Weyl-Kartan geometry with curvature, torsion, and nonmetricity of the Weyl type in spacetime.Within this approach, the tetrads a h μ are not true gauge fields, they represent certain functions of the introduced gauge fields: Lorentzian m a A (rotational r-field), translational k a A (t-field), and dilatational a A (d-field). An equation for the gauge field m a A is as follows:

show abstract

mentioning

confidence: 99%

“…In [6,7], discussed is the case where a spinor field plays the role of external one. The Lagrange density of interaction with the gauge field of the Poincaré-Weyl group is written as , .…”

mentioning

confidence: 99%

“…Let us calculate the foregoing additional, as compared with standard GRT, interaction in the Lagrangian [7]. Calculations for the spinor field of the energy-momentum tensor result in…”

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

The “Gravity Probe B” experiment, interaction between the orbital moment and gauge field, and a gravidiamagnetic effect

Baburova

Frolov

2011

Russ Phys J

Self Cite

View full text Add to dashboard Cite

show abstract

“…These identities were taken from the monograph [10] where a theory of gravity was studied without introducing a scalar field. However, as shown in [11][12][13], from the requirements of the Poicar´e-Weyl gauge theory of gravity follows the necessity of introducing a scalar field as an additional component of the metric tensor. The properties of this field coincide with those of the scalar field introduced by Dirac [14].…”

Section: Differential Identities In a Theory Of Gravity With A Dirac mentioning

confidence: 99%

The use of symbolic calculations in post-Riemannian and multidimensional theories of gravity

2011

Self Cite

View full text Add to dashboard Cite

We have developed new methods of using symbolic computer calculations for four-and higherdimensional, geometrically generalized spaces. In particular,we work with differential identities in order to check the variational field equations of a conformal theory of gravity with a scalar field in Weyl-Cartan space. To simplify the navigation, we have worked out a graphic user interface, making it possible to solve problems of a post-Riemannian theory of gravity in Weyl-Cartan space, as well as those of the KaluzaKlein five-dimensional unified theory of gravity and electromagnetism, in particular, in the external form formalism.

show abstract

Non-minimal geometry–matter couplings in Weyl–Cartan space–times: f(R,T,Q,Tm) gravity

Harkó

Myrzakulov

2021

Physics of the Dark Universe

View full text Add to dashboard Cite

A Weyl-Cartan space-time model based on the gauge principle

Cited by 20 publications

References 29 publications

The “Gravity Probe B” experiment, interaction between the orbital moment and gauge field, and a gravidiamagnetic effect

The “Gravity Probe B” experiment, interaction between the orbital moment and gauge field, and a gravidiamagnetic effect

The use of symbolic calculations in post-Riemannian and multidimensional theories of gravity

Non-minimal geometry–matter couplings in Weyl–Cartan space–times: f(R,T,Q,Tm) gravity

Contact Info

Product

Resources

About