Faculté des sciences Exacteshttp://depot.umc.edu.dz/handle/123456789/128552026-05-01T04:47:00Z2026-05-01T04:47:00ZRotating Charged Cosmic Strings from Seiberg-Witten Non Commutative GeometryMenacera, L.Aissaouia, H.http://depot.umc.edu.dz/handle/123456789/140422023-01-21T19:59:52Z2016-12-14T00:00:00ZRotating Charged Cosmic Strings from Seiberg-Witten Non Commutative Geometry
Menacera, L.; Aissaouia, H.
En utilisant la géométrie non commutative de l’espace-temps de Seiberg-Witten, pour la gravitation de jauge d’une corde cosmique charge en rotation on a déterminé explicitement en fonction du paramètre de la non commutativité de l’espace-temps les différentes expressions des veirbeins et les connections de spin non commutatifs nécessaires pour l’étude de l’effet tunnel. En utilisant la méthode BKW, pour des particules spinorielles, on a pu montrer la forme de l’expression de la température de Hawking au voisinage de l’horizon.
2016-12-14T00:00:00ZSolution of the Klein-Gordon oscillator in cosmic string space-time for scalar potentialsMessai, N.Boumali, A.http://depot.umc.edu.dz/handle/123456789/140412023-01-21T19:54:32Z2016-12-15T00:00:00ZSolution of the Klein-Gordon oscillator in cosmic string space-time for scalar potentials
Messai, N.; Boumali, A.
We study in this work the exact solutions of two-dimensional relativistic particuls of spin-0 in the cosmic string background under the effects of scalar potentials as modification in the momentum operator 𝑝𝜇→𝑝𝜇−𝑒𝐴𝜇 and in the mass term 𝑚→𝑚+𝑆(𝜌). In this way, we solve the Klein-Gordon oscillator (KG) and find the energy levels for bound states. Finally the dependance of the scalar potentials interaction with the angular frequency and the energy spectrum has been discussed.
2016-12-15T00:00:00ZIintroduction to(𝑹) gravity and applicationsMansour, H.Si Lakhal, B.http://depot.umc.edu.dz/handle/123456789/140402023-01-21T19:24:36Z2016-12-14T00:00:00ZIintroduction to(𝑹) gravity and applications
Mansour, H.; Si Lakhal, B.
Recent cosmological data show that the universe is expanding at an accelerating rate. This contradicts the results of general relativity, at least for a Universe composed only of matter. To attack this problem, two general ways have been taken: introducing a new type of energy (such as the cosmological constant Λ, dark energy) or modifying the theory of gravitation.
So, several extensions to the theory of gravitation were proposed in order to preserve the positive results of Einstein’s Theory of general relativity. The simplest extension is the so called (𝑅) gravity which consists in replacing the Ricci scalar 𝑅 by a function 𝑓 of it.
Here, we review 𝑓(𝑅) gravity, a modification to general relativity, are all about modifying the Einstein-Hilbert action and taking it to higher orders in the Ricci scalar. There are three versions of (𝑅) modified gravity: Metric, Palatini and Metric-affine gravity.
In this work we will briefly review these versions of (𝑅) modified gravity. We will be essentially interested in examining how does (𝑅) gravity affects the behavior of a charged compact star.
2016-12-14T00:00:00ZPT symmetry in non commutative geometryLeghrib, I.Mebarki, N.Moulla, H.http://depot.umc.edu.dz/handle/123456789/140392023-01-21T18:37:08Z2016-12-15T00:00:00ZPT symmetry in non commutative geometry
Leghrib, I.; Mebarki, N.; Moulla, H.
A PT symmetric and pseudo hermitien hamiltonien is constructed in the context of the seubery. Written non commutatitive space-time and some physical application are presented.
2016-12-15T00:00:00Z