Talks

11101 - 11112 of 18366 Results

Quantum Field Theory 2 - Lecture 9

Francois David CEA Saclay

November 22, 2012

PIRSA:12110010

High Energy Physics
Twisted quantum double model of topological phases

Yidun Wan Fudan University

November 21, 2012

PIRSA:12110079

Condensed Matter
Quantum Signatures of Chaos

Shohini Ghose Wilfrid Laurier University

November 21, 2012

PIRSA:12110072
Twisted quantum double model of topological phases

Yidun Wan Fudan University

November 21, 2012

PIRSA:12110077

Condensed Matter
Statistical Mechanics - Lecture 8

John Berlinsky McMaster University

November 21, 2012

PIRSA:12110028
Quantum Field Theory 2 - Lecture 8

Francois David CEA Saclay

November 21, 2012

PIRSA:12110009

High Energy Physics
Principle of relativity for quantum theory

Marco Zaopo University of Pavia

November 20, 2012

PIRSA:12110073

Quantum Physics
3 point functions in the AdS4/CFT3 correspondence

Agnese Bissi The Abdus Salam International Centre for Theoretical Physics (ICTP)

November 20, 2012

PIRSA:12110053

High Energy Physics
An exact solution of the Dirac equation with CP violation.

Tomislav Prokopec Utrecht University

November 20, 2012

PIRSA:12110076

Astrophysics
Statistical Mechanics - Lecture 7

John Berlinsky McMaster University

November 20, 2012

PIRSA:12110027
Quantum Field Theory 2 - Lecture 7

Francois David CEA Saclay

November 20, 2012

PIRSA:12110008

High Energy Physics
Statistical Mechanics - Lecture 6

John Berlinsky McMaster University

November 19, 2012

PIRSA:12110026

Quantum Field Theory 2 - Lecture 9

Francois David CEA Saclay

November 22, 2012

PIRSA:12110010

High Energy Physics
Twisted quantum double model of topological phases

Yidun Wan Fudan University

November 21, 2012

PIRSA:12110079

Condensed Matter
Quantum Signatures of Chaos

Shohini Ghose Wilfrid Laurier University

November 21, 2012

PIRSA:12110072
Twisted quantum double model of topological phases

Yidun Wan Fudan University

November 21, 2012

PIRSA:12110077

Condensed Matter
Statistical Mechanics - Lecture 8

John Berlinsky McMaster University

November 21, 2012

PIRSA:12110028
Quantum Field Theory 2 - Lecture 8

Francois David CEA Saclay

November 21, 2012

PIRSA:12110009

High Energy Physics
Principle of relativity for quantum theory

Marco Zaopo University of Pavia

November 20, 2012

PIRSA:12110073

Quantum Physics

In a generic quantum experiment we have a given set of devices analyzing some physical property of a system. To each device involved in the experiment we associate a set of random outcomes corresponding to the possible values of the variable analyzed by the device. Devices have apertures that permit physical systems to pass through them. Each aperture is labelled as "input" or "output" depending on whether it is assumed that the aperture lets the system go inside or outside the device. Assuming a particular input/output structure for the devices involved in a generic experiment is equivalent to assume a particular causal structure for the space-time events constituted by the outcomes happening on devices. The joint probability distribution of these outcomes is usually predicted assuming an absolutely defined input/output structure of devices. This means that all observers of the experiment agree on whether an aperture is labelled as "input" or "output". In this talk we show that the mathematical formalism of quantum theory permits to predict the joint probability distribution of outcomes in a generic experiment in such a way that the input/output structure is indeed relative to an observer. This means that two observers of the same experiment can predict the joint probability distribution of outcomes assuming different input/output labels for the apertures. Since input/output structure is the causal structure of the space-time events constituting the outcomes involved in the experiment we conclude that in quantum theory, the causal structure of events may not be regarded as absolute but rather as relative to the observer. We finally point out that properly extending this concept to the cosmological domain could shed light on the problem of dark energy.
3 point functions in the AdS4/CFT3 correspondence

Agnese Bissi The Abdus Salam International Centre for Theoretical Physics (ICTP)

November 20, 2012

PIRSA:12110053

High Energy Physics

I will present recent developments in the computation of three point functions in the AdS4/CFT3 correspondence. More specifically I will consider two different computations for three point functions of operators belonging to the SU(2)XSU(2) sector of ABJM. I will discuss first the generalization of the determinant representation, found by Foda for the three-point functions of the SU(2) sector of N = 4 SYM, to the ABJM theory and secondly semiclassical computations in the case where two operators are heavy and one is light and BPS, comparing the results obtained in the gauge theory side using a coherent state description of the heavy operators with its string theory counterpart calculated holographically.
An exact solution of the Dirac equation with CP violation.

Tomislav Prokopec Utrecht University

November 20, 2012

PIRSA:12110076

Astrophysics

After a brief overview of electroweak baryogenesis, I will show how to construct a solution of the Dirac equation for a CP violating kink wall. This solution nicely reduces to the known solution for a CP violating thin (step) wall. The novel solution can be helpful for studies of baryogenesis sources at strong first order phase transitions, which is relevant for electroweak scale baryogenesis studies.
Statistical Mechanics - Lecture 7

John Berlinsky McMaster University

November 20, 2012

PIRSA:12110027
Quantum Field Theory 2 - Lecture 7

Francois David CEA Saclay

November 20, 2012

PIRSA:12110008

High Energy Physics
Statistical Mechanics - Lecture 6

John Berlinsky McMaster University

November 19, 2012

PIRSA:12110026

Title	Date	Collection	Type	Info
Quantum Field Theory 2 - Lecture 9	2012‑11‑22	12/13 PSI - Quantum Field Theory 2	Course	View details
Twisted quantum double model of topological phases	2012‑11‑21	Quantum Matter	Scientific Series	View details
Quantum Signatures of Chaos	2012‑11‑21	Colloquium	Scientific Series	View details
Twisted quantum double model of topological phases	2012‑11‑21	Quantum Matter	Other	View details
Statistical Mechanics - Lecture 8	2012‑11‑21	12/13 PSI - Statistical Mechanics	Course	View details
Quantum Field Theory 2 - Lecture 8	2012‑11‑21	12/13 PSI - Quantum Field Theory 2	Course	View details
Principle of relativity for quantum theory	2012‑11‑20	Quantum Foundations	Scientific Series	View details
3 point functions in the AdS4/CFT3 correspondence	2012‑11‑20	Quantum Fields and Strings	Scientific Series	View details
An exact solution of the Dirac equation with CP violation.	2012‑11‑20	Cosmology and Gravitation	Scientific Series	View details
Statistical Mechanics - Lecture 7	2012‑11‑20	12/13 PSI - Statistical Mechanics	Course	View details
Quantum Field Theory 2 - Lecture 7	2012‑11‑20	12/13 PSI - Quantum Field Theory 2	Course	View details
Statistical Mechanics - Lecture 6	2012‑11‑19	12/13 PSI - Statistical Mechanics	Course	View details

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Format results

Quantum Field Theory 2 - Lecture 9

Twisted quantum double model of topological phases

Quantum Signatures of Chaos

Twisted quantum double model of topological phases

Statistical Mechanics - Lecture 8

Quantum Field Theory 2 - Lecture 8

Principle of relativity for quantum theory

3 point functions in the AdS4/CFT3 correspondence

An exact solution of the Dirac equation with CP violation.

Statistical Mechanics - Lecture 7

Quantum Field Theory 2 - Lecture 7

Statistical Mechanics - Lecture 6

Quantum Field Theory 2 - Lecture 9

Twisted quantum double model of topological phases

Quantum Signatures of Chaos

Twisted quantum double model of topological phases

Statistical Mechanics - Lecture 8

Quantum Field Theory 2 - Lecture 8

Principle of relativity for quantum theory

3 point functions in the AdS4/CFT3 correspondence

An exact solution of the Dirac equation with CP violation.

Statistical Mechanics - Lecture 7

Quantum Field Theory 2 - Lecture 7

Statistical Mechanics - Lecture 6