Group “Fundamental Interactions”
The quantum gravity team works on a major open question in fundamental physics: how to reconcile general relativity and quantum mechanics. Since gravity describes the dynamics of space-time, this amounts to studying the quantum behavior of time and space.
Loop quantum gravity (LQG) is a major approach aimed at answering this question. In this field, the CPT is at the very forefront, and the team works on the formal definition of the theory, its mathematical aspects, and its applications.
Among the formal developments, the group studies the properties of coherent semiclassical states, which describe quantum geometry, and develops a reformulation of the theory in terms of twistors, which should simplify its application.
The main applications are primordial cosmology and black hole physics. The objective of this research is to identify observable phenomena that could make it possible to test the theory. In the context of cosmology, LQG makes it possible to explore the region close to the initial singularity predicted by classical general relativity. The theory indicates that the current expansion phase of the universe was preceded by a phase of contraction.
LQG also allows the study of the high-curvature region inside black holes (the “Planck star”) and suggests that the central singularity is avoided thanks to quantum effects. The black hole thus becomes unstable: it can explode through a quantum tunneling process, similar to conventional nuclear decay. The team studies the signals produced in this way, which could correspond to observed phenomena such as very high-energy gamma rays or Fast Radio Bursts, possibly caused by explosions of primordial black holes. The quantum structure of space-time is also relevant for studying the thermal properties of black holes and the “information paradox”. The group is at the forefront of the analysis of these questions.
| BRUNO | Matteo | Post Ph.D. | Contact | |
| DIAZ | Juan-Manuel | Ph.D. | Contact | |
| DONA | Pietro | Research teacher | Contact | |
| KRAJEWSKI | Thomas | Research teacher | +33.4.91.26.95.53 | Contact |
| PEREZ | Alejandro | Research teacher Team leader « Quantum Gravity » | +33.4.91.26.97.98 | Contact |
| PIOVESAN | Pierre | Ph.D. | Contact | |
| ROVELLI | Carlo | Research teacher emeritus | +33.4.91.26.96.44 | Contact |
| SPEZIALE | Simone | Researcher Unit leader « Interactions fondamentales » | +33.4.91.26.95.47 | Contact |
| SREERAM | Gowrisankar | Ph.D. | Contact | |
| YAN | Ruijue | Ph.D. | Contact |
Non-Gaussianity as a signature of a quantum theory of gravity
PRX Quantum, 2021, 2 (1), pp.010325. (10.1103/PRXQuantum.2.010325)
A high-performance code for EPRL spin foam amplitudes
Classical and Quantum Gravity, 2021, 38 (22), pp.225010. (10.1088/1361-6382/ac2b0b)
Brown-York charges with mixed boundary conditions
Journal of High Energy Physics, 2021, 11, pp.224. (10.1007/JHEP11(2021)224)
Effective quantum dust collapse via surface matching
Class.Quant.Grav., 2021, 38 (17), pp.175015. (10.1088/1361-6382/ac103e)
Twisted Geometries Coherent States for Loop Quantum Gravity
Classical and Quantum Gravity, 2021, 38 (2), pp.025004. (10.1088/1361-6382/abc273)
Considerations on Quantum Gravity Phenomenology
Universe, 2021, 7 (11), pp.439. (10.3390/universe7110439)
Black holes, Planckian granularity, and the changing cosmological ‘constant’
Gen.Rel.Grav., 2021, 53 (4), pp.40. (10.1007/s10714-021-02807-1)
Black holes
Europhysics News, 2021, 52 (1), pp.16-18. (10.1051/epn/2021102)
Extended corner symmetry, charge bracket and Einstein’s equations
Journal of High Energy Physics, 2021, 09, pp.083. (10.1007/JHEP09(2021)083)
The Weyl BMS group and Einstein’s equations
Journal of High Energy Physics, 2021, 07, pp.170. (10.1007/JHEP07(2021)170)
