Thermal fields and cosmic loops

Steer, Daniele Ann

January 1997

No description available.

530.1

Chiral anomalous dispersion

Sadofyev, Andrey, Sen, Srimoyee

16 February 2018

The linearized Einstein equation describing graviton propagation through a chiral medium appears to be helicity dependent. We analyze features of the corresponding spectrum in a collision-less regime above a flat background. In the long wave-length limit, circularly polarized metric perturbations travel with a helicity dependent group velocity that can turn negative giving rise to a new type of an anomalous dispersion. We further show that this chiral anomalous dispersion is a general feature of polarized modes propagating through chiral plasmas extending our result to the electromagnetic sector.

Anomalies in Field and String Theories

Thermal Field Theory

Holographic studies of thermal gauge theories with flavour

Thomson, Rowan

January 2007

The AdS/CFT correspondence and its extensions to more general gauge/gravity dualities have provided a powerful framework for the study of strongly coupled gauge theories. This thesis explores properties of a large class of thermal strongly coupled gauge theories using the gravity dual. In order to bring the holographic framework closer to Quantum Chromodynamics (QCD), we study theories with matter in the fundamental representation. In particular, we focus on the holographic dual of SU(Nc) supersymmetric Yang-Mills theory coupled to Nf<<Nc flavours of fundamental matter at finite temperature, which is realised as Nf Dq-brane probes in the near horizon (black hole) geometry of Nc black Dp-branes. We explore many aspects of these Dp/Dq brane systems, often focussing on the D3/D7 brane system which is dual to a four dimensional gauge theory. We study the thermodynamics of the Dq-brane probes in the black hole geometry. At low temperature, the branes sit outside the black hole and the meson spectrum is discrete and possesses a mass gap. As the temperature increases, the branes approach a critical solution. Eventually, they fall into the horizon and a phase transition occurs. At large Nc and large 't Hooft coupling, we show that this phase transition is always first order. We calculate the free energy, entropy and energy densities, as well as the speed of sound in these systems. We compute the meson spectrum for brane embeddings outside the horizon and find that tachyonic modes appear where this phase is expected to be unstable from thermodynamic considerations. We study the system at non-zero baryon density nb and find that there is a line of phase transitions for small nb, terminating at a critical point with finite nb. We demonstrate that, to leading order in Nf/Nc, the viscosity to entropy density ratio in these theories saturates the conjectured universal bound. Finally, we compute spectral functions and diffusion constants for fundamental matter in the high temperature phase of the D3/D7 theory.

superstring theory

gauge/gravity duality

D-branes

strongly coupled thermal field theory

Physics

Holographic studies of thermal gauge theories with flavour

Thomson, Rowan

January 2007

The AdS/CFT correspondence and its extensions to more general gauge/gravity dualities have provided a powerful framework for the study of strongly coupled gauge theories. This thesis explores properties of a large class of thermal strongly coupled gauge theories using the gravity dual. In order to bring the holographic framework closer to Quantum Chromodynamics (QCD), we study theories with matter in the fundamental representation. In particular, we focus on the holographic dual of SU(Nc) supersymmetric Yang-Mills theory coupled to Nf<<Nc flavours of fundamental matter at finite temperature, which is realised as Nf Dq-brane probes in the near horizon (black hole) geometry of Nc black Dp-branes. We explore many aspects of these Dp/Dq brane systems, often focussing on the D3/D7 brane system which is dual to a four dimensional gauge theory. We study the thermodynamics of the Dq-brane probes in the black hole geometry. At low temperature, the branes sit outside the black hole and the meson spectrum is discrete and possesses a mass gap. As the temperature increases, the branes approach a critical solution. Eventually, they fall into the horizon and a phase transition occurs. At large Nc and large 't Hooft coupling, we show that this phase transition is always first order. We calculate the free energy, entropy and energy densities, as well as the speed of sound in these systems. We compute the meson spectrum for brane embeddings outside the horizon and find that tachyonic modes appear where this phase is expected to be unstable from thermodynamic considerations. We study the system at non-zero baryon density nb and find that there is a line of phase transitions for small nb, terminating at a critical point with finite nb. We demonstrate that, to leading order in Nf/Nc, the viscosity to entropy density ratio in these theories saturates the conjectured universal bound. Finally, we compute spectral functions and diffusion constants for fundamental matter in the high temperature phase of the D3/D7 theory.

superstring theory

gauge/gravity duality

D-branes

strongly coupled thermal field theory

Physics

A relativistic BCS theory of superconductivity : an experimentally motivated study of electric fields in superconductors

Bertrand, Damien

05 July 2005

In order to understand some of the superconducting mechanisms involving external electric fields at nanometric scales, a Lorentz-covariant extension of the phenomenological Ginzburg-Landau theory has been developed by analogy with the Higgs model of particle physics. Among the specific properties of this model, it has been shown that the phase diagram of some particular geometry submitted to crossed electric and magnetic fields in a stationary situation provides a criterion involving the applied electric field, which could discriminate between the usual Ginzburg-Landau theory and its covariant extension. A sub-microscopic device has been manufactured using microelectronics lithography techniques and was used to perform transport measurements at very low temperatures. However, the experimental measurements of the phase diagram do not reproduce the expectations based whether on the usual or the extended model, suggesting a screening of the electric field by some mechanism which is not accounted for by these phenomenological approaches. A microscopic approach has therefore been developed to extend the s-wave channel of the BCS theory in a relativistic framework, using the functional integral formalism of Finite Temperature Field Theory. In particular, the effective action related to the Ginzburg-Landau free energy was obtained up to second order in the fluctuations of the electromagnetic field and of the superconducting condensate density. This allowed for the identification of the electric and magnetic penetration lengths, inclusive of their dependences on temperature and the chemical potential, which fully explain the experimental results. Several analytic expressions have also been provided for the effective potential in the full range of temperatures between 0 K and the critical temperature, among which the Ginzburg-Landau potential was shown to reproduce this effective potential within the limited range of temperatures where it is expected to be valid.

Field

Mesoscopic

Magnetic

Electric

Effective

Vortices

Action

Thermal field theory

BCS

Penetration length

Superconductivity

Relativistic

PHASE DIAGRAM

Ginzburg-Landau

Modelo de Ginzburg-Landau a partir da teoria de campos a temperatura finita / Ginzburg-Landau model as a field theory at finite temperature

Thiago Cheble Alves Calza

10 February 2015

Conselho Nacional de Desenvolvimento Científico e Tecnológico / Neste trabalho, utilizamos o formalismo de teorias quânticas de campos a temperatura finita, tal como desenvolvidas por Matsubara, aplicado a uma hamiltoniana de N campos escalares com autointeração quártica a N grande. Obtém-se uma expressão, na primeira aproximação quântica, para o coeficiente do termo quadrático da hamiltoniana ("massa quadrada"), renormalizado, como função da temperatura. A partir dela, estudamos o processo de quebra espontânea de simetria. Por outro lado, a mesma hamiltoniana é conhecida como modelo de Ginzburg-Landau na literatura de matéria condensada, e que permite o estudo de transições de fase em materiais ferromagnéticos. A temperatura é introduzida através do termo quadrático na hamiltoniana, de forma linear: é proporcional à diferença entre a variável de temperatura e a temperatura crítica. Tal modelo, porém, possui validade apenas na regi~ao de temperaturas próximas à criticalidade. Como resultado de nossos cálculos na teoria de campos a temperatura finita, observamos que, numa faixa de valores em torno da temperatura crítica, a massa quadrática pode ser aproximada por uma relação linear em relação à variável de temperatura. Isso evidencia a compatibilidade da abordagem de Ginzburg-Landau, na vizinhança da criticalidade, com respeito ao formalismo de campos a temperatura finita. Discutimos também os efeitos causados pela presença de um potencial químico no sistema. / In this work, we use the formalism of quantum field theories at finite temperature, as developed by Matsubara, applied to a Hamiltonian of N scalar fields with quartic self-interaction at N large. We get an expression in the first quantum approximation to the coeficient of the quadratic term of the Hamiltonian ("square mass"), renormalized as a function of temperature. From it, we study the process of spontaneous symmetry breaking. On the other hand, the same Hamiltonian is known as Ginzburg-Landau model in the literature of condensed matter, and allows the study of phase transitions in ferromagnetic materials. The temperature is introduced through the quadratic term in the Hamiltonian of the linear form: is proportional to the difference between the temperature and the critical temperature. This model, however, is valid only in the region of temperatures close to criticality. As a result of our calculations in the field theory at finite temperature, we observed that in a range of values around the critical temperature, the quadratic mass can be approximated by a linear relation with the temperature. This highlights the compatibility of the Ginzburg-Landau approach, in the vicinity of criticality with respect to the formalism of finite temperature field. We also discuss the effects caused by the presence of a chemical potential in the system.

Teoria de campos a temperatura finita

Transições de fase

Thermal Field Theory

Matsubara Formalism

Spontaneous symmetry restoration

Ginzburg-Landau

Modelo de Ginzburg-Landau a partir da teoria de campos a temperatura finita / Ginzburg-Landau model as a field theory at finite temperature

Thiago Cheble Alves Calza

10 February 2015

Conselho Nacional de Desenvolvimento Científico e Tecnológico / Neste trabalho, utilizamos o formalismo de teorias quânticas de campos a temperatura finita, tal como desenvolvidas por Matsubara, aplicado a uma hamiltoniana de N campos escalares com autointeração quártica a N grande. Obtém-se uma expressão, na primeira aproximação quântica, para o coeficiente do termo quadrático da hamiltoniana ("massa quadrada"), renormalizado, como função da temperatura. A partir dela, estudamos o processo de quebra espontânea de simetria. Por outro lado, a mesma hamiltoniana é conhecida como modelo de Ginzburg-Landau na literatura de matéria condensada, e que permite o estudo de transições de fase em materiais ferromagnéticos. A temperatura é introduzida através do termo quadrático na hamiltoniana, de forma linear: é proporcional à diferença entre a variável de temperatura e a temperatura crítica. Tal modelo, porém, possui validade apenas na regi~ao de temperaturas próximas à criticalidade. Como resultado de nossos cálculos na teoria de campos a temperatura finita, observamos que, numa faixa de valores em torno da temperatura crítica, a massa quadrática pode ser aproximada por uma relação linear em relação à variável de temperatura. Isso evidencia a compatibilidade da abordagem de Ginzburg-Landau, na vizinhança da criticalidade, com respeito ao formalismo de campos a temperatura finita. Discutimos também os efeitos causados pela presença de um potencial químico no sistema. / In this work, we use the formalism of quantum field theories at finite temperature, as developed by Matsubara, applied to a Hamiltonian of N scalar fields with quartic self-interaction at N large. We get an expression in the first quantum approximation to the coeficient of the quadratic term of the Hamiltonian ("square mass"), renormalized as a function of temperature. From it, we study the process of spontaneous symmetry breaking. On the other hand, the same Hamiltonian is known as Ginzburg-Landau model in the literature of condensed matter, and allows the study of phase transitions in ferromagnetic materials. The temperature is introduced through the quadratic term in the Hamiltonian of the linear form: is proportional to the difference between the temperature and the critical temperature. This model, however, is valid only in the region of temperatures close to criticality. As a result of our calculations in the field theory at finite temperature, we observed that in a range of values around the critical temperature, the quadratic mass can be approximated by a linear relation with the temperature. This highlights the compatibility of the Ginzburg-Landau approach, in the vicinity of criticality with respect to the formalism of finite temperature field. We also discuss the effects caused by the presence of a chemical potential in the system.

Teoria de campos a temperatura finita

Transições de fase

Thermal Field Theory

Matsubara Formalism

Spontaneous symmetry restoration

Ginzburg-Landau

NONEQUILIBRIUM PROBES OF THE QUARK-GLUON PLASMA

Salehi Kasmaei, Babak

23 July 2021

No description available.

Physics

Particle Physics

Nuclear Physics

quark-gluon plasma

heavy-ion collisions

quantum chromodynamics

Yang-Mills

lattice QCD

relativistic hydrodynamics

collective modes

self-energy

thermal field theory

hard thermal loop perturbation theory

photon

dilepton

quarkonium