Format results
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Cosmology #4
PIRSA:08040008 -
Cosmology #3
PIRSA:08040007 -
Cosmology #2
PIRSA:08030010 -
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Special Topics in Physics - Lecture 14B
Rafael Sorkin Perimeter Institute for Theoretical Physics
PIRSA:08040064 -
Special Topics in Physics - Lecture 14A
Rafael Sorkin Perimeter Institute for Theoretical Physics
PIRSA:08040063 -
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Special Topics in Physics - Lecture 12B
Lee Smolin Perimeter Institute for Theoretical Physics
PIRSA:08040013 -
Special Topics in Physics - Lecture 12A
Lee Smolin Perimeter Institute for Theoretical Physics
PIRSA:08040011 -
Special Topics in Physics - Lecture 11B
Lee Smolin Perimeter Institute for Theoretical Physics
PIRSA:08030026 -
Special Topics in Physics - Lecture 11A
Lee Smolin Perimeter Institute for Theoretical Physics
PIRSA:08030022
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Talk
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Can We Detect Dynamics in Dark Energy?
Marina Cortes Institute for Astrophysics and Space Sciences
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Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050018 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050013 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050017 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050012 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050011 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050016 -
Advanced Topics in Cosmology 4B
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050015 -
Advanced Topics in Cosmology
Viatcheslav Mukhanov Ludwig-Maximilians-Universität München (LMU)
PIRSA:07050010
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Black Holes & Holography - Class 8
Leonard Susskind Stanford University
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Black Holes & Holography - Class 7
Leonard Susskind Stanford University
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Black Holes and Holography: Mini-Course - Lecture 5
Leonard Susskind Stanford University
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Black Holes and Holography: Mini-Course - Lecture 5
Leonard Susskind Stanford University
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Black Holes and Holography: Mini-Course - Lecture 4
Leonard Susskind Stanford University
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Black Holes and Holography: Mini-Course - Lecture 3
Leonard Susskind Stanford University
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Black Holes and Holography: Mini-Course - Lecture 2
Leonard Susskind Stanford University
PIRSA:07030029 -
Black Hole & Holography - Class 1
Leonard Susskind Stanford University
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Introduction to quantum groups 5
Florian Koch Ludwig-Maximilians-Universität München (LMU)
PIRSA:07010031 -
Introduction to quantum groups 4
Florian Koch Ludwig-Maximilians-Universität München (LMU)
PIRSA:07010030 -
Introduction to quantum groups 3
Florian Koch Ludwig-Maximilians-Universität München (LMU)
PIRSA:07010029 -
Introduction to quantum groups 2
Florian Koch Ludwig-Maximilians-Universität München (LMU)
PIRSA:07010028 -
Introduction to quantum groups 1
Florian Koch Ludwig-Maximilians-Universität München (LMU)
PIRSA:07010027
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Introduction to Quantum Information and Computation from a Foundational Standpoint
Jeffrey Bub University of Maryland, College Park
PIRSA:06120048 -
Introduction to Quantum Information and Computation from a Foundational Standpoint
Jeffrey Bub University of Maryland, College Park
PIRSA:06110042 -
Introduction to Quantum Information and Computation from a Foundational Standpoint
Jeffrey Bub University of Maryland, College Park
PIRSA:06110034 -
Introduction to Quantum Information and Computation from a Foundational Standpoint
Jeffrey Bub University of Maryland, College Park
PIRSA:06110033
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Graduate Course on Standard Model & Quantum Field Theory - 17B
Cliff Burgess McMaster University
PIRSA:07040015 -
Graduate Course on Standard Model & Quantum Field Theory - 17A
Cliff Burgess McMaster University
PIRSA:07040014 -
Graduate Course on Standard Model & Quantum Field Theory - 16B
Cliff Burgess McMaster University
PIRSA:07030046 -
Graduate Course on Standard Model & Quantum Field Theory - 16A
Cliff Burgess McMaster University
PIRSA:07030045 -
Graduate Course on Standard Model & Quantum Field Theory - 15B
Cliff Burgess McMaster University
PIRSA:07030038 -
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Graduate Course on Standard Model & Quantum Field Theory - 14B
Cliff Burgess McMaster University
PIRSA:07030019 -
Graduate Course on Standard Model & Quantum Field Theory - 14A
Cliff Burgess McMaster University
PIRSA:07030018
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Superstring Cosmology Mini-Course: Part 4
Senarath de Alwis University of Colorado Boulder
PIRSA:06020006 -
Superstring Cosmology Mini-Course: Part 3
Senarath de Alwis University of Colorado Boulder
PIRSA:06020005 -
Superstring Cosmology Mini-course: Part 2
Senarath de Alwis University of Colorado Boulder
PIRSA:06010022 -
Superstring Cosmology Mini-course: Part 1
Senarath de Alwis University of Colorado Boulder
PIRSA:06010020
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New Horizons In Fundamental Physics
This course is an introduction to some of the most exciting ideas in fundamental physics. The topics are chosen to represent areas of research currently conducted at Perimeter Institute. Each topic will be discussed for one or two weeks and will be lectured by a leading young researcher in each field. From deep conceptual issues on the meaning of quantum theory, passing through very sophisticated theories like string theory and loop quantum gravity all the way to cosmology and quantum information theory, this course is a challenging intellectual adventure. -
Special Topics in Physics
This course will provide an introduction to current research on the problem of time in quantum gravity and cosmology. This is one of the key problems that any successful quantum theory of gravity must solve. Different approaches to quantum gravity assume different answers to fundamental questions such as whether time is emergent or not, whether causality is emergent or not, and what is an observable in a theory of gravity. These problems have aspects which are technical as well as conceptual and philosophical aspects and we will discuss them all as well as their inter-relations. The course will begin with an introduction to the canonical formulation of general relativity and related dynamical systems. We will then study the standard material on the Hamiltonian quantization of general relativity and related time reparametrization invariant systems. This gives us the technical setting in which the problem of time is usually encountered in the contemporary literature on quantum gravity and quantum cosmology. Following this physical introduction we will read the key texts from the history of physics and philosophy concerning the meaning of time, such as Newton, Leibniz, Mach, Einstein etc. This will be followed by readings of papers and books from contemporary sources on this issue by physicists and philosophers. We will focus on two opposite views, the idea that time is emergent in quantum cosmology and the opposing idea that time is fundamental and is perhaps the only aspect of our macroscopic reality that is not emergent. -
Advanced General Relativity
Classes will meet on Wednesdays at the Perimeter Institute for Theoretical Physics, starting on January 9, 2008. The first class meeting is from 10:30 am to 12:00 pm in the Bob Room. The second class meeting is from 4:00 pm to 5:30 pm in the Alice Room. -
Spontaneous Broken Symmetry
A series of 8 lectures, 2 hours each on Spontaneous Broken Symmetry. -
Introduction to Supersymmetry
Alex Buchel gives an introduction to supersymmetry. -
Advanced Topics in Cosmology mini-course 2007
Advanced Topics in Cosmology mini-course 2007 with Slava Mukhanov -
Black Holes and Holography: Mini-Course - 2007
Black Holes and Holography: Mini-Course with Lenny Susskind -
Introduction to Quantum Groups 1 - 2007
From Quantum Mechanics to Quantum Groups The notion of 'quantization' commonly used in textbooks of quantum mechanics has to be specified in order to turn it into a defined mathematical operation. We discuss that on the trails of Weyl's phase space deformation, i.e. we introduce the Weyl-Moyal starproduct and the deformation of Poisson-manifolds. Generalizing from this, we understand, why Hopf-algebras are the most genuine way to apply 'quantization' to various other algebraic objects - and why this has direct physical applications. -
Quantum Error Correction Course 2007
An in-depth introduction to quantum error correction, fault-tolerant quantum computing, and related topics. Covers stabilizer codes, CSS codes, higher-dimensional codes, specific code constructions, entanglement purification protocols, and quantum channel capacity. Also bounds on quantum error correction: quantum Hamming bound, quantum Singleton bound, linear programming bounds and the quantum MacWilliams identity; and principles of fault-tolerant quantum computation: fault-tolerant error measurement, fault-tolerant gate design, the threshold for fault-tolerant quantum computation, and topological fault-tolerance. -
Introduction to Quantum Information and Computation from a Foundational Standpoint
Graduate Course on the Standard Model and Quantum Field Theory -
Graduate Course on the Standard Model and Quantum Field Theory - 2006/2007
Graduate Course on the Standard Model and Quantum Field Theory -
Superstring Cosmology Mini-Course - 2006
Shanta's mini-course