Admissible states for quantum fields and allowed temperatures of extremal black holes

Borrott, Andrew Robert

January 1998

No description available.

530.1

Quantum field theory; Curved spacetime

インフレーション中の量子トンネリング : 量子ゆらぎの非線形解析 / Quantum Tunneling During Inflation: Non-linear Analysis of the Quantum Fluctuations

杉村, 和幸

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18070号 / 理博第3948号 / 新制||理||1569(附属図書館) / 30928 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 佐々木 節, 教授 田中 貴浩, 教授 畑 浩之 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

inflation

cosmological perturbation theory

quntum tunneling

non-Gaussianity

QFT on curved spacetime

400

Quantum information and relativity: harvesting entanglement in different setups / Informação quântica e relatividade: colhendo emaramento em configurações variadas

Ota, Iara Naomi Nobre

31 July 2018

The aim of this work is present the phenomenon denoted entanglement harvesting. We begin by introducing entanglement historically. Following, we go beyond the one particle theory in flat spacetime and introduce Quantum Field Theory in Curved Spacetime, showing two famous consequences: the Unruh effect and the Hawking radiation. Finally, we analyze entanglement harvesting for two Unruh-deWitt detectors. In the fisrt example, we see that there is a \"sudden death\" point of entanglement harvesting when the detectors are near the BTZ black hole event horizon, due to redshift effect and Hawking radiation. Then, we compare the phenomenon for different scenarios, and find out that it is sensitive to the structure of spacetime. Finally, we see how detectors\' parameters affect it and find out that the smoothness of the switching of the detectors\' coupling to the field is extremely relevant. We also see how the parameters can be used to optimize entanglement harvested. / O objetivo desse trabalho é apresentar o fenômeno denotado colheita de emaranhamento. Primeiramente fazemos uma introdução histórica de emaranhamento de estados quânticos. Em seguida, introduzimos a Teoria Quântica de Campos no Espaço-tempo Curvo, como um passo além da teoria quântica de uma partícula no espaço-tempo plano, e demonstramos dois resultados famosos da teoria: o efeito Unruh e a radiação Hawking. Por fim, fazemos uma analise do fenômeno de colheita de emaranhamento para dois detectores Unruh-deWitt. Nosso primeiro exemplo mostra que há um ponto de \"morte súbita\" do fenômeno quando os detectores se aproximam do horizonte de eventos de um buraco negro de BTZ, que é uma consequência do efeito de redshift e da radiação Hawking. Em seguida, comparamos o fenômeno em cenários diferentes, e observamos que a colheita de emaranhamento é sensível à estrutura do espaço-tempo. Por último, analisamos como os parâmetros dos detectores afetam a colheita de emaranhamento, e vemos que a suavidade em que o acoplamento dos detectores com o campo é \"ligado\" e \"desligado\" é extremamente relevante. Também analisamos como podemos usar os parâmetros dos detectores para otimizar a quantidade de emaranhamento colhida.

Colheita de emaranhamento

Emaranhamento

Entanglement

Harvesting entanglement

Quantum field theory in curved spacetime

Particle Definitions and the Information Loss Paradox

Venditti, Alexander

13 August 2013

An investigation of information loss in black hole spacetimes is performed. We demon- strate that the definition of particles as energy levels of the Harmonic oscillator will not have physical significance in general and is thus not a good instrument to study the ra- diation of black holes. This is due to the ambiguity of the choice of coordinates on the phase space of the quantum field. We demonstrate how to identify quantum states in the functional Schr ̈dinger picture. o We demonstrate that information is truly lost in the case of a Vaidya black hole (a black hole formed from null dust) if we neglect back reaction. This is done by quantizing the constrained classical system of a Klein-Gordon field in a Vaidya background. The interaction picture of quantum mechanics can be applied to this system. We find a physically well motivated vacuum state for a spherically symmetric space- time with an extra conformal Killing vector. We also demonstrate how to calculate the response of a particle detector in the a LeMaitre-Tolman-Bondi spacetime with a self- similarity. Finally, some of the claims and confusion surrounding Unruh radiation, Hawking radiation and the equivalence principle are investigated and shown to be false.

black hole

quantum field theory

information loss

curved spacetime

Hawking radiation

Unruh radiation

particles

Klein Gordon

0798

Particle Definitions and the Information Loss Paradox

Venditti, Alexander

13 August 2013

An investigation of information loss in black hole spacetimes is performed. We demon- strate that the definition of particles as energy levels of the Harmonic oscillator will not have physical significance in general and is thus not a good instrument to study the ra- diation of black holes. This is due to the ambiguity of the choice of coordinates on the phase space of the quantum field. We demonstrate how to identify quantum states in the functional Schr ̈dinger picture. o We demonstrate that information is truly lost in the case of a Vaidya black hole (a black hole formed from null dust) if we neglect back reaction. This is done by quantizing the constrained classical system of a Klein-Gordon field in a Vaidya background. The interaction picture of quantum mechanics can be applied to this system. We find a physically well motivated vacuum state for a spherically symmetric space- time with an extra conformal Killing vector. We also demonstrate how to calculate the response of a particle detector in the a LeMaitre-Tolman-Bondi spacetime with a self- similarity. Finally, some of the claims and confusion surrounding Unruh radiation, Hawking radiation and the equivalence principle are investigated and shown to be false.

black hole

quantum field theory

information loss

curved spacetime

Hawking radiation

Unruh radiation

particles

Klein Gordon

0798

Quantum information and relativity: harvesting entanglement in different setups / Informação quântica e relatividade: colhendo emaramento em configurações variadas

Iara Naomi Nobre Ota

31 July 2018

The aim of this work is present the phenomenon denoted entanglement harvesting. We begin by introducing entanglement historically. Following, we go beyond the one particle theory in flat spacetime and introduce Quantum Field Theory in Curved Spacetime, showing two famous consequences: the Unruh effect and the Hawking radiation. Finally, we analyze entanglement harvesting for two Unruh-deWitt detectors. In the fisrt example, we see that there is a \"sudden death\" point of entanglement harvesting when the detectors are near the BTZ black hole event horizon, due to redshift effect and Hawking radiation. Then, we compare the phenomenon for different scenarios, and find out that it is sensitive to the structure of spacetime. Finally, we see how detectors\' parameters affect it and find out that the smoothness of the switching of the detectors\' coupling to the field is extremely relevant. We also see how the parameters can be used to optimize entanglement harvested. / O objetivo desse trabalho é apresentar o fenômeno denotado colheita de emaranhamento. Primeiramente fazemos uma introdução histórica de emaranhamento de estados quânticos. Em seguida, introduzimos a Teoria Quântica de Campos no Espaço-tempo Curvo, como um passo além da teoria quântica de uma partícula no espaço-tempo plano, e demonstramos dois resultados famosos da teoria: o efeito Unruh e a radiação Hawking. Por fim, fazemos uma analise do fenômeno de colheita de emaranhamento para dois detectores Unruh-deWitt. Nosso primeiro exemplo mostra que há um ponto de \"morte súbita\" do fenômeno quando os detectores se aproximam do horizonte de eventos de um buraco negro de BTZ, que é uma consequência do efeito de redshift e da radiação Hawking. Em seguida, comparamos o fenômeno em cenários diferentes, e observamos que a colheita de emaranhamento é sensível à estrutura do espaço-tempo. Por último, analisamos como os parâmetros dos detectores afetam a colheita de emaranhamento, e vemos que a suavidade em que o acoplamento dos detectores com o campo é \"ligado\" e \"desligado\" é extremamente relevante. Também analisamos como podemos usar os parâmetros dos detectores para otimizar a quantidade de emaranhamento colhida.

Colheita de emaranhamento

Emaranhamento

Entanglement

Harvesting entanglement

Quantum field theory in curved spacetime

Quantum instability of the Cauchy horizon in Reissner–Nordström–deSitter spacetime

Hollands, Stefan, Wald, Robert M., Zahn, Jochen

27 April 2023

In classical general relativity, the values of elds on spacetime are uniquely determined by their values at an initial time within the domain of dependence of this initial data surface. However, it may occur that the spacetime under consideration extends beyond this domain of dependence, and elds, therefore, are not entirely determined by their initial data. This occurs, for example, in the well-known (maximally) extended Reissner–Nordström or Reissner–Nordström–deSitter (RNdS) spacetimes. The boundary of the region determined by the initial data is called the ‘Cauchy horizon.’ It is located inside the black hole in these spacetimes. The strong cosmic censorship conjecture asserts that the Cauchy horizon does not, in fact, exist in practice because the slightest perturbation (of the metric itself or the matter elds) will become singular there in a sufciently catastrophic way that solutions cannot be extended beyond the Cauchy horizon. Thus, if strong cosmic censorship holds, the Cauchy horizon will be converted into a ‘nal singularity,’ and determinism will hold. Recently, however, it has been found that, classically this is not the case in RNdS spacetimes in a certain range of mass, charge, and cosmological constant. In this paper, we consider a quantum scalar eld in RNdS spacetime and show that quantum theory comes to the rescue of strong cosmic censorship. We nd that for any state that is nonsingular (i.e., Hadamard) within the domain of dependence, the expected stress-tensor blows up with afne parameter, V, along a radial null geodesic transverse to the Cauchy horizon as TVV ∼ C/V 2 with C independent of the state and C 6= 0 generically in RNdS spacetimes. This divergence is stronger than in the classical theory and should be sufcient to convert the Cauchy horizon into a singularity through which the spacetime cannot be extended as a (weak) solution of the semiclassical Einstein equation. This behavior is expected to be quite general, although it is possible to have C = 0 in certain special cases, such as the BTZ black hole

info:eu-repo/classification/ddc/530

ddc:530

Black holes as a gateway to the quantum : classical and semi-classical explorations / Les trous noirs comme porte d'entrée vers le quantique : explorations classique et semi-classique

De Lorenzo, Tommaso

18 September 2018

Depuis 1916, l'étude des Trous Noirs a soulevé des questions intrigantes. Seulement certaines ont été résolues. En effet, nous faisons face à des régimes où s’entremêlent la théorie quantique et l'espace-temps. Les TN comme porte d'entrée pour comprendre la nature quantique de la gravité. Ma thèse a été entièrement dédiée à ce domaine central de la physique théorique, avec pour but la compréhension la plus large possible des débats autour de ces questions. C'est ainsi qu'ont été produits des résultats originaux qui constituent le cœur de ce manuscrit. 1-Les surfaces de volume maximal des TN sont étudiées. Un TN astrophysique terminera sa vie avec une aire planckienne de $10^{-70} m^2$ dissimulant $10^5$ fois le volume de l'univers observable. Ceci peut avoir des conséquences sur la viabilité du "remnant scenario" comme solution au paradoxe de l'information. 2-Le scénario "trou-noir-trou-blanc" est fortement instable. Une modification minimale est proposée pour résoudre ce problème. 3-Une généralisation des quatre lois de la thermodynamique des TN est démontrée pour des cônes de lumière s'intersectant dans un espace de Minkowski. 4-On étudie des espaces conformellement plats où de telles lois acquièrent une interprétation thermodynamique standard. Le plus simple est l'espace-temps de Bertotti-Robinson, connu pour encoder la géométrie proche de l'horizon d'un TN chargé. 5-Pour peu que le bon tenseur énergie-impulsion soit identifié, les équations du champ Einstein-Cartan peuvent être retrouvées comme l'équation d'état d'un équilibre thermodynamique, comme dans le cas original de la RG. Ces résultats contribuent au débat intense sur les questions cruciales posées ci-dessus. / Since 1916 intriguing questions have arisen from the study of Black Holes (BH). Only some of them have been resolved. Indeed, we are faced with regimes where the yet unknown interplay between quantum theory and spacetime unveils. BH physics is a gateway to the quantum nature of gravity. My thesis has been completely devoted to this central domain of theoretical physics, with the guiding aim of understanding in the widest possible manner the debate around those questions. The process has produced original results that constitute the main core of the manuscript. 1- The maximal volume surfaces of evaporating BHs are studied. An astrophysical BH will end its life with an external planckian area $10^{-70} m^2$ hiding $10^5$ times the volume of our observable Universe. This can have consequences on the viability of the “remnant scenario” as solution to the BH information paradox. 2- The “black-hole-to-white-hole scenario” is analyzed. The model is shown to be strongly unstable, and a minimal resolutive modification is proposed. 3- A generalisation of the four laws of BH thermodynamics is proven for intersecting light cones in Minkowski spacetime. 4- Conformally flat spaces where such laws acquire the standard thermodynamical interpretation are studied. The simplest one is the Bertotti-Robinson spacetime, known to encode the near-horizon geometry of a charged BH. 5- It is shown that, if the correct energy-momentum tensor is identified, the Eintein-Cartan’s field equations can be recovered as a thermodynamical equilibrium equation of state just like in the GR original case. Such results contribute to the intense debate on the opening crucial questions.

Trous noirs

Gravité

Relativité generale

Black holes

Gravity

General Relativity

Quantum field theory in curved spacetime

530

Local Equilibrium States in Quantum Field Theory in Curved Spacetime / Lokale Gleichgewichtszustände in der Quantenfeldtheorie auf gekrümmter Raumzeit

Solveen, Christoph

11 April 2012

No description available.

530 Physik

RDI 500

RDI 640

RJG 200

Physics

lokales thermisches Gleichgewicht

local thermal equilibrium

Quantum Field Theory in Curved Spacetime

33.24

33.21

33.28

O grupo de renormalização em modelos de gravitação

Teixeira, Poliane de Morais

17 February 2016

Submitted by Renata Lopes (renatasil82@gmail.com) on 2017-06-08T15:27:56Z No. of bitstreams: 1 polianedemoraisteixeira.pdf: 833138 bytes, checksum: 6826a43bfd3baaedb0691bb15c3c425e (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2017-06-26T19:06:07Z (GMT) No. of bitstreams: 1 polianedemoraisteixeira.pdf: 833138 bytes, checksum: 6826a43bfd3baaedb0691bb15c3c425e (MD5) / Made available in DSpace on 2017-06-26T19:06:07Z (GMT). No. of bitstreams: 1 polianedemoraisteixeira.pdf: 833138 bytes, checksum: 6826a43bfd3baaedb0691bb15c3c425e (MD5) Previous issue date: 2016-02-17 / Nessa tese, exploramos diferentes aspectos do grupo de renormalização (GR) em Gravitação Quântica. Especificamente, estudamos o GR aplicado a três diferentes modelos. Começamos por estudar o GR on-shell usando para isso o modelo de gravidade com torção proposto por Cartan, fizemos o tratamento quântico dessa teoria. Em seguida, mostramos em detalhes os cálculos do estudo da teoria semiclássica usando para isso o método da renormalização física, baseada na subtração de momentos. Nesta parte nós damos os detalhes da derivação dos fatores de forma gravitacionais, usando o método do heat kernel para três teorias massivas: campo escalar, campo vetorial e campo fermiônico. O que nos leva ao análogo gravitacional do teorema de desacoplamento de Appelquist e Carazzone. Nessa parte apenas refizemos os cálculos já desenvolvidos em um artigo de Gorbar e Shapiro, mas agora em detalhes minuciosos para cada etapa calculada. E na última parte, uma análise do grupo funcional de renormalização (GFR) foi feita, aplicando essa técnica também ao modelo de gravidade semiclássica, onde a teoria abordada foi a de um campo escalar com acoplamento não-mínimo no espaço-tempo curvo. / On this thesis, we explored differents aspects of the renormalization group (RG) in Quantum Gravity. Specifically, we studied the RG applied to three differents models. We began studying the RG on-shell and we used for that the model of gravity with torsion proposed by Cartan, we made the quantum treatment of this theory. Then, we showed in details the calculations of the study of semi-classical theory, using for that, the method of physical renormalization, based on the momentum subtraction. On this part, we gave the details of the derivation of gravitational form factors, using the method of the heat kernel for three massive theories: scalar field, vector field and fermionic field which leads us to the gravitational analogue of the decoupling theorem from Appelquist and Carazzone. In this part, we just remade the calculations already undertaken in a paper by Gorbar and Shapiro, but now in minute details for each step calculated. On the last part, an analysis of the functional renormalization group (FRG) was made, applying this technique also to the model of semiclassical gravity, where the theory addressed was a theory with a scalar field with non-minimal coupling in curved spacetime.

CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA

Grupo de renormalização

Gravitação quântica

Gravidade semiclássica

Espaço-tempo curvo

Renormalization group

Quantum gravity

Semiclassical gravity

Curved spacetime