Your search keyword '"Buzzegoli, M."' showing total 4 results

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

Author

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

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, General Relativity and Quantum Cosmology, Mathematical Physics, Nuclear Theory

Abstract

We derive a general exact form of the phase space distribution function and the thermal expectation values of local operators for the free quantum scalar field at equilibrium with rotation and acceleration in flat space-time without solving field equations in curvilinear coordinates. After factorizing the density operator with group theoretical methods, we obtain the exact form of the phase space distribution function as a formal series in thermal vorticity through an iterative method and we calculate thermal expectation values by means of analytic continuation techniques. We separately discuss the cases of pure rotation and pure acceleration and derive analytic results for the stress-energy tensor of the massless field. The expressions found agree with the exact analytic solutions obtained by solving the field equation in suitable curvilinear coordinates for the two cases at stake and already - or implicitly - known in literature. In order to extract finite values for the pure acceleration case we introduce the concept of analytic distillation of a complex function. For the massless field, the obtained expressions of the currents are polynomials in the acceleration/temperature ratios which vanish at $2\pi$, in full accordance with the Unruh effect., Comment: 38 pages, 1 figure. Final proofread version published in JHEP

Published

2020

2. Reworking the Zubarev's approach to non-equilibrium quantum statistical mechanics

Author

Becattini, F., Buzzegoli, M., and Grossi, E.

Subjects

Condensed Matter - Statistical Mechanics, General Relativity and Quantum Cosmology, Nuclear Theory

Abstract

In this work the non-equilibrium density operator approach introduced by Zubarev more than 50 years ago to describe quantum systems at local thermodynamic equilibrium is revisited. This method - which was used to obtain the first ''Kubo" formula of shear viscosity, is especially suitable to describe quantum effects in fluids. This feature makes it a viable tool to describe the physics of the Quark Gluon Plasma in relativistic nuclear collisions., Comment: 9 pages, 1 figure. Submitted to special issue of Particles: "Nonequilibrium Phenomena in Strongly Correlated System"

Published

2019

3. General thermodynamic equilibrium with axial chemical potential for the free Dirac field

Author

Buzzegoli, M. and Becattini, F.

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, Nuclear Theory

Abstract

We calculate the constitutive equations of the stress-energy tensor and the currents of the free massless Dirac field at thermodynamic equilibrium with acceleration and rotation and a conserved axial charge by using the density operator approach. We carry out an expansion in thermal vorticity to the second order with finite axial chemical potential $\mu_A$. The obtained coefficients of the expansion are expressed as correlators of angular momenta and boost operators with the currents. We confirm previous observations that the axial chemical potential induces non-vanishing components of the stress-energy tensor at first order in thermal vorticity due to breaking of parity invariance of the density operator with $\mu_A \ne 0$. The appearance of these components might play an important role in chiral hydrodynamics., Comment: 29 pages, final version published in JHEP, typos

Published

2018

4. General equilibrium second-order hydrodynamic coefficients for free quantum fields

Author

Buzzegoli, M., Grossi, E., and Becattini, F.

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, Nuclear Theory

Abstract

We present a systematic calculation of the corrections of the stress-energy tensor and currents of the free boson and Dirac fields up to second order in thermal vorticity, which is relevant for relativistic hydrodynamics. These corrections are non-dissipative because they survive at general thermodynamic equilibrium with non vanishing mean values of the conserved generators of the Lorentz group, i.e. angular momenta and boosts. Their equilibrium nature makes it possible to express the relevant coefficients by means of correlators of the angular-momentum and boost operators with stress-energy tensor and current, thus making simpler to determine their so-called "Kubo formulae". We show that, at least for free fields, the corrections are of quantum origin and we study several limiting cases and compare our results with previous calculations. We find that the axial current of the free Dirac field receives corrections proportional to the vorticity independently of the anomalous term., Comment: 33 pages, final version published in JHEP, typos

Published

2017