Your search keyword '"Perche, T. Rick"' showing total 7 results

1. A path integral formulation for particle detectors: the Unruh-DeWitt model as a line defect.

Author

Burbano, Ivan M., Perche, T. Rick, and de S. L. Torres, Bruno

Subjects

*PARTICLE detectors, *PATH integrals, *FEYNMAN diagrams, *OPERATOR theory, *DEGREES of freedom

Abstract

Particle detectors are an ubiquitous tool for probing quantum fields in the context of relativistic quantum information (RQI). We formulate the Unruh-DeWitt (UDW) particle detector model in terms of the path integral formalism. The formulation is able to recover the results of the model in general globally hyperbolic spacetimes and for arbitrary detector trajectories. Integrating out the detector's degrees of freedom yields a line defect that allows one to express the transition probability in terms of Feynman diagrams. Inspired by the light-matter interaction, we propose a gauge invariant detector model whose associated line defect is related to the derivative of a Wilson line. This is another instance where nonlocal operators in gauge theories can be interpreted as physical probes for quantum fields. [ABSTRACT FROM AUTHOR]

Published

2021

2. Antiparticle detector models in QFT.

Author

Perche, T. Rick and Martín-Martínez, Eduardo

Subjects

*ANTIPARTICLES, *DETECTORS, *PARTICLE detectors

Abstract

We analyze families of particle detector models that linearly couple to different kinds of fermionic and bosonic fields. We also study the response of these detectors to particle and antiparticle excitations of the field. We propose a simple linear complex scalar particle detector model that captures the fundamental features of fermionic field detectors similarly to how the Unruh-DeWitt model captures the features of the light matter interaction. We also discuss why we do not need to limit ourselves to quadratic models commonly employed in past literature. Namely, we provide a physically motivated mechanism that restores U(1) symmetry in these linear complex models. [ABSTRACT FROM AUTHOR]

Published

2021

3. General features of the thermalization of particle detectors and the Unruh effect.

Author

Perche, T. Rick

Subjects

*UNRUH effect, *PARTICLE detectors, *QUANTUM field theory, *QUANTUM operators, *DETECTORS

Abstract

We study the thermalization of smeared particle detectors that couple locally to any operator in a quantum field theory in curved spacetimes. We show that if the field state satisfies the Kubo-Martin-Schwinger condition with inverse temperature β with respect to the detector's local notion of time evolution, reasonable assumptions ensure that the probe thermalizes to the temperature 1/β in the limit of long interaction times. Our method also imposes bounds on the size of the system with respect to its proper acceleration and spacetime curvature in order to accurately probe the Kubo-Martin-Schwinger temperature of the field. We then apply this formalism to a uniformly accelerated detector probing the Minkowski vacuum of any CPT symmetric quantum field theory, and show that the detector thermalizes to the Unruh temperature, independently of the operator it couples to. This exemplifies yet again the robustness of the Unruh effect, even when arbitrary smeared detectors are used to probe general operators in a quantum field theory. [ABSTRACT FROM AUTHOR]

Published

2021

4. Broken covariance of particle detector models in relativistic quantum information.

Author

Martín-Martínez, Eduardo, Perche, T. Rick, and Torres, Bruno de S. L.

Subjects

*PARTICLE detectors, *MOTION detectors, *DETECTORS

Abstract

We show that the predictions of commonly used spatially smeared particle detectors coupled to quantum fields are not generally covariant outside the pointlike limit. This lack of covariance manifests itself as an ambiguity in the time-ordering operation. We analyze how the breakdown of covariance affects typical detector models in quantum field theory such as the Unruh-DeWitt model. Specifically, we show how the violations of covariance depend on the state of the detectors-field system, the shape and state of motion of the detectors, and the spacetime geometry. Furthermore, we provide the tools to explicitly evaluate the magnitude of the violation and identify the regimes where the predictions of smeared detectors are either exactly or approximately covariant in perturbative analyses, thus providing limits of validity of smeared particle detector models. [ABSTRACT FROM AUTHOR]

Published

2021

5. Neutrino flavor oscillations without flavor states.

Author

de S. L. Torres, Bruno, Perche, T. Rick, Landulfo, André G. S., and Matsas, George E. A.

Subjects

*NEUTRINO oscillation, *PARTICLE detectors, *NEUTRINO mass, *FLAVOR, *QUANTUM measurement, *NEUTRINOS

Abstract

We analyze the problem of neutrino oscillations via a fermionic particle detector model inspired by the physics of the Fermi theory of weak interactions. The model naturally leads to a description of emission and absorption of neutrinos in terms of localized two-level systems. By explicitly including source and detector as part of the dynamics, the formalism is shown to recover the standard results for neutrino oscillations without mention to "flavor states," which are ill defined in quantum field theory. This illustrates how particle detector models provide a powerful theoretical tool to approach the measurement issue in quantum field theory and emphasizes that the notion of flavor states, although sometimes useful, must not play any crucial role in neutrino phenomenology. [ABSTRACT FROM AUTHOR]

Published

2020

6. Particle detectors as witnesses for quantum gravity.

Author

Faure, Rémi, Perche, T. Rick, and Torres, Bruno de S. L.

Subjects

*PARTICLE detectors, *GRAVITATIONAL fields, *WITNESSES, *DETECTORS, *QUANTUM gravity

Abstract

We present a model for the coupling of nonrelativistic quantum systems with a linearized gravitational field from a Lagrangian formulation. The coupling strongly resembles the light-matter interaction models that are known to be well approximated by the Unruh-DeWitt detector model for interactions with quantum fields. We then apply our model to linearized quantum gravity, which allows us to propose a detector based setup that can in principle probe the quantum nature of the gravitational field. [ABSTRACT FROM AUTHOR]

Published

2020

7. General relativistic quantum optics: Finite-size particle detector models in curved spacetimes.

Author

Martín-Martínez, Eduardo, Perche, T. Rick, and Torres, Bruno de S. L.

Subjects

*PARTICLE detectors, *QUANTUM field theory, *MOTION detectors, *COORDINATE transformations, *PREDICTION theory, *QUANTUM optics

Abstract

We propose a fully covariant model for smeared particle detectors in quantum field theory in curved spacetimes. We show how effects related to accelerated motion of the detector and the curvature of spacetime influence the way different observers assign an interaction Hamiltonian between the detector and the field. The fully covariant formulation explicitly leaves the physical predictions of the theory invariant under general coordinate transformations, hence providing a description of particle detector models (e.g., Unruh-DeWitt detectors, models for the light-matter interaction, etc.) that is suitable for arbitrary trajectories in general spacetime backgrounds. [ABSTRACT FROM AUTHOR]

Published

2020