Format results
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Numerical Methods Lecture - 230207
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23020001 -
Numerical Methods Lecture - 230202
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23020000 -
Numerical Methods Lecture - 230201
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23020003 -
Numerical Methods Lecture - 230131
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23010008 -
Numerical Methods Lecture - 230126
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23010007 -
Numerical Methods Lecture - 230124
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23010006 -
Numerical Methods Lecture - 230120
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23010011 -
Numerical Methods Lecture - 230119
Erik Schnetter Perimeter Institute for Theoretical Physics
PIRSA:23010005
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Fitting models to data using Markov Chain Monte Carlo
Dustin Lang Perimeter Institute for Theoretical Physics
PIRSA:23010076 -
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Topological quantum matter and quantum computing
Tsung-Cheng Lu (Peter) Perimeter Institute for Theoretical Physics
PIRSA:23010084 -
Topological quantum matter and quantum computing
Tsung-Cheng Lu (Peter) Perimeter Institute for Theoretical Physics
PIRSA:23010086
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Quantum Field Theory II - Lecture 221213
PIRSA:22120005 -
Quantum Field Theory II - Lecture 221212
PIRSA:22120004 -
Quantum Field Theory II - Lecture 221207
PIRSA:22120003 -
Quantum Field Theory II - Lecture 221206
PIRSA:22120002 -
Quantum Field Theory II - Lecture 221205
PIRSA:22120001 -
Quantum Field Theory II - Lecture 221202
PIRSA:22120000 -
Quantum Field Theory II - Lecture 221130
PIRSA:22110011 -
Quantum Field Theory II - Lecture 221128
PIRSA:22110010
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Statistical Physics - Lecture 221213
PIRSA:22120011 -
Statistical Physics - Lecture 221212
PIRSA:22120010 -
Statistical Physics - Lecture 221207
PIRSA:22120009 -
Statistical Physics - Lecture 221206
PIRSA:22120008 -
Statistical Physics - Lecture 221205
PIRSA:22120007 -
Statistical Physics - Lecture 221201
PIRSA:22120006 -
Statistical Physics - Lecture 221130
PIRSA:22110019 -
Statistical Physics - Lecture 221128
PIRSA:22110018
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QFT2 - Quantum Electrodynamics - Afternoon Lecture
Cliff Burgess McMaster University
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QFT2 - Quantum Electrodynamics - Afternoon Lecture
Cliff Burgess McMaster University
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QFT2 - Quantum Electrodynamics - Afternoon Lecture
Cliff Burgess McMaster University
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QFT2 - Quantum Electrodynamics - Afternoon Lecture
Cliff Burgess McMaster University
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Quantum adiabatic speedup on a class of combinatorial optimization problems
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Madelyn Cain Harvard University
- Madelyn Cain
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Towards an artificial Muse for new ideas in Quantum Physics
Mario Krenn Max Planck Institute for the Science of Light
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Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks
Friederike Metz L'Ecole Polytechnique Federale de Lausanne (EPFL)
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A Study of Neural Network Field Theories
Anindita Maiti Perimeter Institute for Theoretical Physics
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Representing quantum states with spiking neural networks
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Stefanie Czischek University of Ottawa
- Stefanie Czischek
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Adaptive Quantum State Tomography with Active Learning
Hannah Lange Ludwig-Maximilians-Universitiät München (LMU)
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Topological superconductivity in twisted double-layer high-Tc cuprates: Theory and experimental signatures
Marcel Franz University of British Columbia
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Stacking Induced Spontaneous Polarization in Rhombohedral MoS2
Ziliang Ye University of British Columbia
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Z2 spin liquids in spin-S Kitaev honeycomb model via parton construction
Han Ma Perimeter Institute for Theoretical Physics
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Non-Fermi liquids and quantum criticality in multipolar Kondo systems
Yong-Baek Kim University of Toronto
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Quantum Field Theory I - Lecture 221108
PIRSA:22110003 -
Quantum Field Theory I - Lecture 221107
PIRSA:22110002 -
Quantum Field Theory I - Lecture 221102
PIRSA:22110001 -
Quantum Field Theory I - Lecture 221101
PIRSA:22110000 -
Quantum Field Theory I - Lecture 221031
Gang Xu Perimeter Institute for Theoretical Physics
PIRSA:22100057 -
Quantum Field Theory I - Lecture 221028
Gang Xu Perimeter Institute for Theoretical Physics
PIRSA:22100056 -
Quantum Field Theory I - Lecture 221026
Gang Xu Perimeter Institute for Theoretical Physics
PIRSA:22100055 -
Quantum Field Theory I - Lecture 221024
Gang Xu Perimeter Institute for Theoretical Physics
PIRSA:22100054
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Relativity - Lecture 221102
PIRSA:22110025 -
Relativity - Lecture 221101
PIRSA:22110024 -
Relativity - Lecture 221031
PIRSA:22100087 -
Relativity - Lecture 221028
PIRSA:22100086 -
Relativity - Lecture 221026
PIRSA:22100085 -
Relativity - Lecture 221024
PIRSA:22100084
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Welcoming Remarks
PIRSA:22100114 -
Session 1 - Mykola Semenyakin
Mykola Semenyakin Perimeter Institute for Theoretical Physics
PIRSA:22100115 -
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Special Guest Talk - 'Science Opportunities Underground: Neutrinos and Dark Matter'
Arthur B. McDonald Queen's University
PIRSA:22100064 -
Special Guest Talk - 'How to take a picture of a black hole'
Shep Doeleman Harvard University
PIRSA:22100066 -
Perimeter Researcher Talk - 'CHIME: the Canadian Hydrogen Intensity Mapping Experiment'
Kendrick SmithPIRSA:22100067 -
Panel Session: Luck vs Grit
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Asimina Arvanitaki Perimeter Institute
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Arthur B. McDonald Queen's University
- Katie Mack
PIRSA:22100068 -
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Special Guest Talk - 'The serendipitous road to a Nobel prize'
Anthony Leggett University of Illinois Urbana-Champaign
PIRSA:22100069 -
Perimeter Researcher Talk - 'Measurement as a shortcut to long-range entangled matter'
Timothy Hsieh Perimeter Institute for Theoretical Physics
PIRSA:22100070 -
Special Guest Talk - 'From nonlinear optics to high intensity laser physics'
Donna Strickland University of Waterloo
PIRSA:22100071
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Numerical Methods (2022/2023)
This course teaches basic numerical methods that are widely used across many fields of physics. The course is based on the Julia programming language. Topics include an introduction to Julia, linear algebra, Monte Carlo methods, differential equations, and are based on applications by researchers at Perimeter. The course will also teach principles of software engineering ensuring reproducible results. -
Gravitational Physics (2022/2023)
The main objective of this course is to discuss some advanced topics in gravitational physics and its applications to high energy physics. Necessary mathematical tools will be introduced on the way. These mathematical tools will include a review of differential geometry (tensors, forms, Lie derivative), vielbeins and Cartan’s formalism, hypersurfaces, Gauss-Codazzi formalism, and variational principles (Einstein-Hilbert action & Gibbons-Hawking term). Several topics in black hole physics including the Kerr solution, black hole astrophysics, higher-dimensional black holes, black hole thermodynamics, Euclidean action, and Hawking radiation will be covered. Additional advanced topics will include domain walls, brane world scenarios, Kaluza-Klein theory and KK black holes, Gregory-Laflamme instability, and gravitational instantons
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Symmetries Graduate School 2023
The goal of this Winter School on Symmetries is to introduce graduate students to the effectiveness of symmetry principles across subjects and energy scales.
From Noether’s celebrated theorem to the development of the standard model of particle physics, from Landau’s to Wilson’s classification of phases of matter and phase transitions, symmetries have been key to 20th century physics. But in the last decades novel and more subtle incarnations of the symmetry principle have shown us the way to unlocking new and unexpected phases of quantum matter, infrared and holographic properties of the quantum gravitational interaction, as well as to advancements in pure mathematics to mention a few.
The Graduate Winter School on Symmetries will introduce students and young researchers to a variety of applications of the symmetry principle. These will be chosen across contemporary research topics in both theoretical physics and mathematics. Our goal is to create a synergistic environment where ideas and techniques can ultimately spread across disciplines. This will be achieved through a combination of mini-courses, colloquia, and discussion sessions led in collaboration with the students themselves.
https://pirsa.org/C23008
Territorial Land AcknowledgementPerimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.
Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.
We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.
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Quantum Field Theory II (2022/2023)
The course has three parts. In the first part of the course, the path integral formulation of non-relativistic quantum mechanics and the functional integral formulation of quantum field theory are developed. The second part of the course covers renormalization and the renormalization group. Finally, non-abelian gauge theories are quantized using functional integral techniques.
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Statistical Physics (2022/2023)
The course begins by discussing several topics in equilibrium statistical physics including phase transitions and the renormalization group. The second part of the course covers non-equilibrium statistical physics including kinetics of aggregation, spin dynamics, population dynamics, and complex networks.
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Special Topics in Physics - QFT2: Quantum Electrodynamics (Cliff Burgess)
This course uses quantum electrodynamics (QED) as a vehicle for covering several more advanced topics within quantum field theory, and so is aimed at graduate students that already have had an introductory course on quantum field theory. Among the topics hoped to be covered are: gauge invariance for massless spin-1 particles from special relativity and quantum mechanics; Ward identities; photon scattering and loops; UV and IR divergences and why they are handled differently; effective theories and the renormalization group; anomalies.
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New Frontiers in Machine Learning and Quantum
This workshop will bring together a group of young trendsetters working at the frontier of machine learning and quantum information. The workshop will feature two days of talks, and ample time for participants to interact and form new collaborations in the inspiring environment of the Perimeter Institute. Topics will include machine learning, quantum field theory, quantum information, and unifying theoretical concepts.
Territorial Land AcknowledgementPerimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.
Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.
We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.
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Quantum Matter Workshop
The goal of this conference is for quantum matter researchers at Perimeter, University of British Columbia, and University of Toronto to share their recent work with each other, to facilitate discussion and collaboration.
Territorial Land AcknowledgementPerimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.
Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.
We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.
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Quantum Field Theory I (2022/2023)
The course starts by looking for a quantum theory that is compatible with special relativity, without assuming fields are fundamental. Nevertheless fields turn out to be a very good, maybe inevitable mathematical tool for formulating and studying such a relativistic quantum theory. The second part of the course introduces the Dirac theory and canonically quantizes it. It also quantizes the Maxwell field theory. The Feynman diagram technique for perturbation theory is developed and applied to the scattering of relativistic fermions and photons. Renormalization of quantum electrodynamics is done to one-loop order.
Prerequisite: PSI Quantum Theory course or equivalently Graduate level Quantum Mechanics and QFT of scalar theory
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Relativity (2022/2023)
This is an introductory course on general relativity (GR). We shall cover the basics of differential geometry and its applications to Einstein’s theory of gravity. The plan is to discuss black holes, gravitational waves, and observational evidence for GR, as well as to cover some of the more advanced topics. -
POSTDOC WELCOME 2022
Join us on Monday October 24 to welcome our new cohort of postdocs at Perimeter Institute at the Postdoc Welcome 2022! Each new postdoc will be given 5 minutes to introduce themselves to the PI Community. The time will be used to tell us a little bit about themselves and to showcase their current research. These presentations are very casual and should not be misconstrued as formal talks. Some discussion will follow the presentations, whereby current PI Residents may have the opportunity to ask questions.
Conference Schedule:
9:30AM - 11AM - short talks session 1 in Sky room.
11:00AM -11:30AM - coffee break in 1st floor Bistro
11:30AM - 1:00PM - short talks session 2 in Sky room.
1:00PM - 2:00PM - group lunch in the Bistro in 2nd floor Bistro (new postdocs, postdoc reps)
2:00PM - 5:30PM - off-site activity (new postdocs, existing postdocs)https://pirsa.org/C22042
Territorial Land Acknowledgement
Perimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.
Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.
We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.
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The Day of Discovery
Join us for a day that celebrates the advance of human knowledge! Come and hear from scientific luminaries responsible for defining the modern landscape of physics and working to transform it in the future. Presentations by Nobel and Breakthrough Prize winners will describe some of the most exciting topics in science today, followed by talks by Perimeter researchers on how these are being pursued now, and culminating with animated panel conversations on how breakthrough science was, is and will be done.
https://pirsa.org/C22040
Territorial Land Acknowledgement
Perimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.
Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.
We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.