Format results
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Foundations and Interpretation of Quantum Theory - Lecture 21
Vladimir Manucharyan Harvard University
PIRSA:10040017 -
Foundations and Interpretation of Quantum Theory - Lecture 20
Michel Devoret Yale Univeristy - Department of Applied Physics
PIRSA:10030008 -
Foundations and Interpretation of Quantum Theory - Lecture 19
Anthony Leggett University of Illinois Urbana-Champaign
PIRSA:10030025 -
Foundations and Interpretation of Quantum Theory - Lecture 18
Anthony Leggett University of Illinois Urbana-Champaign
PIRSA:10030007 -
Foundations and Interpretation of Quantum Theory - Lecture 17
Lev Vaidman Tel Aviv University
PIRSA:10030024 -
Foundations and Interpretation of Quantum Theory - Lecture 16
Lev Vaidman Tel Aviv University
PIRSA:10030006 -
Foundations and Interpretation of Quantum Theory - Lecture 15
Chris Fuchs University of Massachusetts Boston
PIRSA:10030023 -
Foundations and Interpretation of Quantum Theory - Lecture 14
Chris Fuchs University of Massachusetts Boston
PIRSA:10030005
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High energy scattering
Joao Penedones L'Ecole Polytechnique Federale de Lausanne (EPFL)
PIRSA:09110029
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Introduction to Effective Field Theory - Lecture 12
Cliff Burgess McMaster University
PIRSA:09120006 -
Introduction to Effective Field Theory - Lecture 10B
Cliff Burgess McMaster University
PIRSA:09110018 -
Introduction to Effective Field Theory - Lecture 10
Cliff Burgess McMaster University
PIRSA:09110014 -
Introduction to Effective Field Theory - Lecture 9C
Cliff Burgess McMaster University
PIRSA:09110137 -
Introduction to Effective Field Theory - Lecture 9B
Cliff Burgess McMaster University
PIRSA:09110017 -
Introduction to Effective Field Theory - Lecture 9A
Cliff Burgess McMaster University
PIRSA:09110013 -
Introduction to Effective Field Theory - Lecture 8C
Cliff Burgess McMaster University
PIRSA:09110133 -
Introduction to Effective Field Theory - Lecture 8B
Cliff Burgess McMaster University
PIRSA:09110016
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PSI - Relativity (PHYS 604) - 17
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090076 -
PSI - Relativity (PHYS 604) - 16
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090075 -
PSI - Relativity (PHYS 604) - 15
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090074 -
Relativity - Core (PHYS 604) - Lecture 14
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090073 -
Relativity - Core (PHYS 604) - Lecture 13
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090072 -
Relativity - Core (PHYS 604) - Lecture 12
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090069 -
Relativity - Core (PHYS 604) - Lecture 11
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090068 -
PSI - Relativity (PHYS 604) - 10
Robert Myers Perimeter Institute for Theoretical Physics
PIRSA:09090067
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Non-Equilibrium Systems (PHYS 606) - Lecture 10
Sidney Redner Boston University - Department of Physics
PIRSA:09110116 -
Non-Equilibrium Systems (PHYS 606) - Lecture 9
Sidney Redner Boston University - Department of Physics
PIRSA:09110115 -
Non-Equilibrium Systems (PHYS 606) - Lecture 8
Sidney Redner Boston University - Department of Physics
PIRSA:09110114 -
Non-Equilibrium Systems (PHYS 606) - Lecture 7
Sidney Redner Boston University - Department of Physics
PIRSA:09110113 -
Non-Equilibrium Systems (PHYS 606) - Lecture 6
Sidney Redner Boston University - Department of Physics
PIRSA:09110112 -
Non-Equilibrium Systems (PHYS 606) - Lecture 5
Sidney Redner Boston University - Department of Physics
PIRSA:09110109 -
Non-Equilibrium Systems (PHYS 606) - Lecture 4
Sidney Redner Boston University - Department of Physics
PIRSA:09110108 -
Non-Equilibrium Systems (PHYS 606) - Lecture 3
Sidney Redner Boston University - Department of Physics
PIRSA:09110107
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Condensed Matter Review (PHYS 637) - Lecture 15
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010067 -
Condensed Matter Review (PHYS 637) - Lecture 14
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010066 -
Condensed Matter Review (PHYS 637) - Lecture 13
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010065 -
Condensed Matter Review (PHYS 637) - Lecture 12
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010064 -
Condensed Matter Review (PHYS 637) - Lecture 11
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010063 -
Condensed Matter Review (PHYS 637) - Lecture 10
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010041 -
Condensed Matter Review (PHYS 637) - Lecture 9
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010060 -
Condensed Matter Review (PHYS 637) - Lecture 8
Xiao-Gang Wen Massachusetts Institute of Technology (MIT) - Department of Physics
PIRSA:10010059
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Cosmology - Review (PHYS 621) - Lecture 15
Parampreet Singh Louisiana State University
PIRSA:09120097 -
Cosmology - Review (PHYS 621) - Lecture 14
Parampreet Singh Louisiana State University
PIRSA:09120096 -
Cosmology - Review (PHYS 621) - Lecture 13
Parampreet Singh Louisiana State University
PIRSA:09120095 -
Cosmology - Review (PHYS 621) - Lecture 12
Parampreet Singh Louisiana State University
PIRSA:09120094 -
Cosmology - Review (PHYS 621) - Lecture 11
Parampreet Singh Louisiana State University
PIRSA:09120093 -
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Foundations and Interpretation of Quantum Theory
After a review of the axiomatic formulation of quantum theory, the generalized operational structure of the theory will be introduced (including POVM measurements, sequential measurements, and CP maps). There will be an introduction to the orthodox (sometimes called Copenhagen) interpretation of quantum mechanics and the historical problems/issues/debates regarding that interpretation, in particular, the measurement problem and the EPR paradox, and a discussion of contemporary views on these topics. The majority of the course lectures will consist of guest lectures from international experts covering the various approaches to the interpretation of quantum theory (in particular, many-worlds, de Broglie-Bohm, consistent/decoherent histories, and statistical/epistemic interpretations, as time permits) and fundamental properties and tests of quantum theory (such as entanglement and experimental tests of Bell inequalities, contextuality, macroscopic quantum phenomena, and the problem of quantum gravity, as time permits). Organizers: Raymond Laflamme and Joseph Emerson -
Scattering in AdS and CFT correlation functions
Non credit PI mini-course -
General Relativity for Cosmology
This course begins by introducing the differential geometry of Lorentzian manifolds from scratch and then builds up quickly to the advanced framework in terms of differential forms and the vielbein formalism. These methods are then used to define general relativity, also as a gauge theory. We then study some of general relativity's deeper properties, such as the formalism of spinors, and aspects of the causal structure and singularities. One key goal is to lay the foundations for students who wish to proceed to studies in quantum gravity. We then apply general relativity to cosmological models and to cosmological perturbation theory. Thereby, we are covering the theory of cosmic inflation which is very successful in predicting, in particular, the properties cosmic microwave background radiation. -
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09/10 PSI - Condensed Matter (Review)
Condensed Matter (Review) -
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