Your search keyword '"Buzzegoli, M."' showing total 3 results

1. Exact equilibrium distributions in statistical quantum field theory with rotation and acceleration: Dirac field.

Author

Palermo, A., Buzzegoli, M., and Becattini, F.

Subjects

*QUANTUM field theory, *STATISTICAL equilibrium, *DISTRIBUTION (Probability theory), *UNRUH effect, *DENSITY matrices, *SPIN polarization, *ROTATIONAL motion

Abstract

We derive the general exact forms of the Wigner function, of mean values of conserved currents, of the spin density matrix, of the spin polarization vector and of the distribution function of massless particles for the free Dirac field at global thermodynamic equilibrium with rotation and acceleration, extending our previous results obtained for the scalar field. The solutions are obtained by means of an iterative method and analytic continuation, which lead to formal series in thermal vorticity. In order to obtain finite values, we extend to the fermionic case the method of analytic distillation introduced for bosonic series. The obtained mean values of the stress-energy tensor, vector and axial currents for the massless Dirac field are in agreement with known analytic results in the special cases of pure acceleration and pure rotation. By using this approach, we obtain new expressions of the currents for the more general case of combined rotation and acceleration and, in the pure acceleration case, we demonstrate that they must vanish at the Unruh temperature. [ABSTRACT FROM AUTHOR]

Published

2021

2. Spin polarization induced by magnetic field and the relativistic Barnett effect.

Author

Buzzegoli, M.

Subjects

*SPIN polarization, *MAGNETIC fields, *QUANTUM field theory, *THERMAL equilibrium, *MAGNETIC moments, *THERMAL plasmas

Abstract

First, I study the analogy between the magnetization of a material and the spin polarization of particles in a fluid. Using the relativistic version of the Barnett effect, i.e. the magnetization of a material induced by mechanical rotation, the spin polarization induced by thermal vorticity is obtained within a purely classical model, where spin is treated as an intrinsic magnetic moment and rotation is included as a non-inertial effect. I argue that since spin polarization induced by thermal vorticity can be obtained in a classical theory, it can not be dominated by quantum anomalies. Second, the spin polarization induced by magnetic field is obtained for a fluid at local thermal equilibrium using statistical quantum field theory. The obtained formula is valid beyond the weak field approximation and when contributions from the non-homogeneity of the magnetic field are small. The exact form of spin polarization is studied for a free Dirac field at global equilibrium, and, like magnetic susceptibility, it oscillates according to the de Haas - van Alphen effect. Finally, I briefly review how magnetic field contributes to the difference between the spin polarization of Λ and Λ ¯ observed in heavy-ion collisions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Anomalous gravitomagnetic moment and nonuniversality of the axial vortical effect at finite temperature.

Author

Buzzegoli, M. and Kharzeev, Dmitri E.

Subjects

*QUANTUM field theory, *QUANTUM fluids, *TEMPERATURE effect, *RADIATIVE corrections, *ANGULAR momentum (Mechanics), *FERMIONS, *HADRON interactions

Abstract

The coupling between the spin of a massive Dirac fermion and the angular momentum of the medium, i.e. the gravitomagnetic moment, is shown here to be renormalized by QED interactions at finite temperature. This means that the anomalous gravitomagnetic moment (AGM) does not vanish, and implies that thermal effects can break the Einstein equivalence principle in quantum field theory, as argued previously. We also show that the AGM causes radiative corrections to the axial current of massive fermions induced by vorticity in quantum relativistic fluids, similarly to the previous findings for massless fermions. The radiative QCD effects on the AGM should significantly affect the production of polarized hadrons in heavy-ion collisions. [ABSTRACT FROM AUTHOR]

Published

2021