Joseph Buchbinder (Tomsk State P Department of Theoretical Physics, Ilya Shapiro (Universidade Federal de Departamento de Fisica - ICE
Introduction to Quantum Field Theory with Applications to Quantum Gravity
Joseph Buchbinder (Tomsk State P Department of Theoretical Physics, Ilya Shapiro (Universidade Federal de Departamento de Fisica - ICE
Introduction to Quantum Field Theory with Applications to Quantum Gravity
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This textbook presents a detailed introduction to the general concepts of quantum field theory, with special emphasis on principal aspects of functional methods and renormalization in gauge theories, and includes an introduction to semiclassical and perturbative quantum gravity in flat and curved spacetimes.
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This textbook presents a detailed introduction to the general concepts of quantum field theory, with special emphasis on principal aspects of functional methods and renormalization in gauge theories, and includes an introduction to semiclassical and perturbative quantum gravity in flat and curved spacetimes.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Oxford Graduate Texts
- Verlag: Oxford University Press
- Seitenzahl: 544
- Erscheinungstermin: 9. Februar 2023
- Englisch
- Abmessung: 246mm x 173mm x 29mm
- Gewicht: 1048g
- ISBN-13: 9780198872344
- ISBN-10: 0198872348
- Artikelnr.: 65609575
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
- Oxford Graduate Texts
- Verlag: Oxford University Press
- Seitenzahl: 544
- Erscheinungstermin: 9. Februar 2023
- Englisch
- Abmessung: 246mm x 173mm x 29mm
- Gewicht: 1048g
- ISBN-13: 9780198872344
- ISBN-10: 0198872348
- Artikelnr.: 65609575
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
Ioseph Buchbinder graduated from Tomsk State University (Russia) with the highest degree (1988, doctor of sciences) in Physical and Mathematical ciences. From 1988 to the present time, he is a professor and head of Department of Theoretical Physics at Tomsk State Pedagogical University. He was a visiting professor at University of Pennsylvania, University of Maryland, University of North Carolina, University of Hannover, Humboldt University Berlin, Cambridge University, University of Sao Paulo, University of Juiz de Fora, University of Hiroshima, Wroclaw University, University of Brno, University of Beer Sheva. Was a supervisor of 21 Ph.D thesis, co-author of Effective Action in Quantum Gravity (IOPP, 1992; with S.D. Odintsov and I.L. Shapiro) and Ideas and Methods of Supersymmetry and Supergravity (IOPP, 1995, 1998; with S.M. Kuzenko), and author of around 300 papers in Statistical Mechanics, Quantum Field Theory, Quantum Gravity, Supersymmetry and Supergravity, and Higher Spin Field Theory. Ilya Shapiro graduated from Tomsk State University Physics (Russia) with the highest degree (1993, doctor of sciences) in Physical and Mathematical Sciences. In 1994-1996 was post-doc in the Department of Theoretical Physics in the University of Zaragoza, from 1996 visiting and from 2000 permanent professor at the Federal University of Juiz de Fora, Brazil. In 2014 he was visiting professor at the University of Geneva. Between 1985 and 2020 he supervised 13 Ph.D. theses, and has been author and co-author of 150+ articles and three books, including Effective Action In Quantum Gravity (IOPP, 1992), an introductory textbook on Newtonian Mechanics (two editions, in Brazil and in Germany), and an introductory textbook on Tensors and Relativity (Springer, 2019).
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References
PART I INTRODUCTION TO QUANTUM FIELD THEORY
1: Introduction
2: Relativistic Symmetry
3: Lagrange formalism in field theory
4: Field Models
5: Canonical Quantization of Free Fields
6: Scattering Matrix and Green Functions
7: Functional Integrals
8: Perturbation Theory
9: Renormalization
10: Quantum Gauge Theories
PART II SEMICLASSICAL AND QUANTUM GRAVITY MODELS
11: Brief Review of General Relativity.
12: Classical fields in curved spacetime
13: Quantum fields in curved spacetime: renormalization
14: One-loop divergences
15: Renormalization group in curved space
16: Non-local form factors in flat and curved spacetime
17: Conformal anomaly and anomaly-induced action
18: General Notions of Perturbative Quantum Gravity
19: Massive ghosts in higher derivative models
20: One-loop renormalization in quantum gravity
21: Renormalization group in perturbative quantum gravity
22: Induced gravity approach
23: Final remarks on Part II
References