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SIGMA 7 (2011), 083, 10 pages arXiv:1103.4057
https://doi.org/10.3842/SIGMA.2011.083
Contribution to the Special Issue “Loop Quantum Gravity and Cosmology”
A Lorentz-Covariant Connection for Canonical Gravity
Marc Geiller a, Marc Lachièze-Rey a, Karim Noui b and Francesco Sardelli b
a) Laboratoire APC, Université Paris Diderot Paris 7, 75013 Paris, France
b) LMPT, Université Francois Rabelais, Parc de Grandmont, 37200 Tours, France
Received May 27, 2011, in final form August 20, 2011; Published online August 24, 2011
Abstract
We construct a Lorentz-covariant connection in the context of first order canonical gravity with non-vanishing Barbero-Immirzi parameter. To do so, we start with the phase space formulation derived from the canonical analysis of the Holst action in which the second class constraints have been solved explicitly. This allows us to avoid the use of Dirac brackets. In this context, we show that there is a ''unique'' Lorentz-covariant connection which is commutative in the sense of the Poisson bracket, and which furthermore agrees with the connection found by Alexandrov using the Dirac bracket. This result opens a new way toward the understanding of Lorentz-covariant loop quantum gravity.
Key words:
canonical gravity; first order gravity; Lorentz-invariance; second class constraints.
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References
- Ashtekar A.,
New variables for classical and quantum gravity,
Phys. Rev. Lett. 57 (1986), 2244-2247.
- Barbero J.F.,
Real Ashtekar variables for Lorentzian signature space-times,
Phys. Rev. D 51 (1995), 5507-5510,
gr-qc/9410014.
- Immirzi G.,
Real and complex connections for canonical gravity,
Classical Quantum Gravity 14 (1997), L177-L181,
gr-qc/9612030.
- Holst S.,
Barbero's Hamiltonian derived from a generalized Hilbert-Palatini action,
Phys. Rev. D 53 (1996), 5966-5969,
gr-qc/9511026.
- Ashtekar A., Lewandowski J.,
Quantum theory of geometry. I. Area operators,
Classical Quantum Gravity 14 (1997), A55-A81,
gr-qc/9602046.
- Rovelli C., Smolin L.,
Discreteness of area and volume in quantum gravity,
Nuclear Phys. B 442 (1995), 593-619,
gr-qc/9411005.
- Agulló I., Barbero J.F., Díaz-Polo J., Fernández-Borja E., Villaseñor E.J.S.,
Black hole state counting in loop quantum gravity: a number-theoretical approach,
Phys. Rev. Lett. 100 (2008), 211301, 4 pages,
gr-qc/0005126.
- Ashtekar A., Baez J.C., Krasnov K.,
Quantum geometry of isolated horizons and black hole entropy,
Adv. Theor. Math. Phys. 4 (2000), 1-94,
gr-qc/0005126.
- Meissner K.A.,
Black-hole entropy in loop quantum gravity,
Classical Quantum Gravity 21 (2004), 5245-5251,
gr-qc/0407052.
- Rovelli C.,
Black hole entropy from loop quantum gravity,
Phys. Rev. Lett. 77 (1996), 3288-3291,
gr-qc/9603063.
- Rovelli C., Thiemann T.,
The Immirzi parameter in quantum general relativity,
Phys. Rev. D 57 (1998), 1009-1014,
gr-qc/9705059.
- Henneaux M., Teitelboim C.,
Quantization of gauge systems,
Princeton University Press, Princeton, NJ, 1992.
- Alexandrov S.Yu., Vassilevich D.V.,
Path integral for the Hilbert-Palatini and Ashtekar gravity,
Phys. Rev. D 58 (1998), 124029, 13 pages,
gr-qc/9806001.
- Alexandrov S.,
SO(4,C)-covariant Ashtekar-Barbero gravity and the Immirzi parameter,
Classical Quantum Gravity 17 (2000), 4255-4268,
gr-qc/0005085.
- Alexandrov S., Vassilevich D.,
Area spectrum in Lorentz-covariant loop gravity,
Phys. Rev. D 64 (2001), 044023, 7 pages,
gr-qc/0103105.
- Alexandrov S., Livine E.R.,
SU(2) loop quantum gravity seen from covariant theory,
Phys. Rev. D 67 (2003), 044009, 15 pages,
gr-qc/0209105.
- Barros e Sá N.,
Hamiltonian analysis of general relativity with the Immirzi parameter,
Internat. J. Modern Phys. D 10 (2001), 261-272,
gr-qc/0006013.
- Peldán P.,
Actions for gravity, with generalizations: a review,
Classical Quantum Gravity 11 (1994), 1087-1132,
gr-qc/9305011.
- Geiller M., Lachièze-Rey M., Noui K.,
A new look at Lorentz-covariant loop quantum gravity,
Phys. Rev. D 84 (2011), 044002, 19 pages,
arXiv:1105.4194.
- Cianfrani F., Montani G.,
Towards loop quantum gravity without the time gauge,
Phys. Rev. Lett. 102 (2009), 091301,
arXiv:0811.1916.
- Samuel J.,
Is Barbero's Hamiltonian formulation a gauge theory of Lorentzian gravity?,
Classical Quantum Gravity 17 (2000), L141-L148,
gr-qc/0005095.
- Rovelli C., Speziale S.,
Lorentz covariance of loop quantum gravity,
Phys. Rev. D 83 (2011), 104029, 6 pages,
arXiv:1012.1739.
- Engle J., Livine E., Pereira R., Rovelli C.,
LQG vertex with finite Immirzi parameter,
Nuclear Phys. B 799 (2008), 136-149,
arXiv:0711.0146.
- Freidel L., Krasnov K.,
A new spin foam model for 4D gravity,
Classical Quantum Gravity 25 (2008), 125018, 36 pages,
arXiv:0708.1595.
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