Format results
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Talk
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Classical and Quantum Chaos 2021/2022 - Lecture 14
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030058 -
Classical and Quantum Chaos 2021/2022 - Lecture 13
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030057 -
Classical and Quantum Chaos 2021/2022 - Lecture 12
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030056 -
Classical and Quantum Chaos 2021/2022 - Lecture 11
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030055 -
Classical and Quantum Chaos 2021/2022 - Lecture 10
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030054 -
Classical and Quantum Chaos 2021/2022 - Lecture 9
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030053 -
Classical and Quantum Chaos 2021/2022 - Lecture 8
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030052 -
Classical and Quantum Chaos 2021/2022 - Lecture 7
Meenu Kumari National Research Council Canada (NRC)
PIRSA:22030112
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Talk
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030081 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030080 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030079 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030078 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030077 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030076 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030075 -
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Quantum Information 2021/2022
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Eduardo Martin-Martinez Institute for Quantum Computing (IQC)
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Philippe Allard Guerin Royal Military College Saint-Jean
PIRSA:22030074 -
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Talk
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Quantum Fields and Strings 2021/2022 - Lecture 3
Dan Wohns Perimeter Institute for Theoretical Physics
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Quantum Fields and Strings - Lecture 2
Dan Wohns Perimeter Institute for Theoretical Physics
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Quantum Fields and Strings 2021/2022 -Lecture 1
Dan Wohns Perimeter Institute for Theoretical Physics
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Talk
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Geometry and topology for physicists 2021/2022 - Lecture 14
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030072 -
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Geometry and topology for physicists 2021/2022 - Lecture 13
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030071 -
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Geometry and topology for physicists 2021/2022 - Lecture 12
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030070 -
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Geometry and topology for physicists 2021/2022 - Lecture 10
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030068 -
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Geometry and topology for physicists 2021/2022 - Lecture 9
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030067 -
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Geometry and topology for physicists 2021/2022 - Lecture 8
Kevin Costello Perimeter Institute for Theoretical Physics
PIRSA:22030066 -
Geometry and topology for physicists 2021/2022 - Lecture 7
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030065 -
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Geometry and topology for physicists 2021/2022 - Lecture 6
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Kevin Costello Perimeter Institute for Theoretical Physics
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Giuseppe Sellaroli Perimeter Institute for Theoretical Physics
PIRSA:22030064 -
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Talk
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PSI Lecture - Condensed Matter - Lecture 15
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 14
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 13
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 12
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 11
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 10
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 9
Aaron Szasz Lawrence Berkeley National Laboratory
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PSI Lecture - Condensed Matter - Lecture 8
Aaron Szasz Lawrence Berkeley National Laboratory
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Talk
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Talk
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Summer Undergrad 2020 - Numerical Methods (A) - Lecture 5
Aaron Szasz Lawrence Berkeley National Laboratory
PIRSA:20060013 -
Summer Undergrad 2020 - Numerical Methods (A) - Lecture 4
Aaron Szasz Lawrence Berkeley National Laboratory
PIRSA:20060012 -
Summer Undergrad 2020 - Numerical Methods (A) - Lecture 3
Aaron Szasz Lawrence Berkeley National Laboratory
PIRSA:20060011 -
Summer Undergrad 2020 - Numerical Methods (A) - Lecture 2
Aaron Szasz Lawrence Berkeley National Laboratory
PIRSA:20050041 -
Summer Undergrad 2020 - Numerical Methods (A) - Lecture 1
Aaron Szasz Lawrence Berkeley National Laboratory
PIRSA:20050040
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Classical and Quantum Chaos 2021/2022
Chaos, popularly known as the butterfly effect, is a ubiquitous phenomenon that renders a system's evolution unpredictable due to extreme sensitivity to initial conditions. Within the context of classical physics, it often occurs in nonintegrable Hamiltonian systems and is characterized by positive Lyapunov exponents. On the other hand, the notion of nonintegrability and chaos in quantum physics is still not well-understood and is an area of active research. Several signatures have been studied in the literature to identify quantum chaos but all of them fall short in some way or the other. In this course, we will first discuss the notions of classical integrability, and classical chaos and its characterization with Lyapunov exponents. Then, we will discuss a few well-studied signatures of quantum chaos and the subtleties associated with them. -
Quantum Information 2021/2022
We will review the notion of entanglement in quantum mechanics form the point of view of information theory, and how to quantify it and distinguish it from classical correlations. We will derive Bell inequalities and discuss their importance, and how quantum information protocols can use entanglement as a resource. Then we will analyze measurement theory in quantum mechanics, the notion of generalized measurements and quantum channels and their importance in the processing and transmission of information. We will introduce the notions of quantum circuits and see some of the most famous algorithms in quantum information processing, as well as in quantum cryptography. We will also talk about the notion of distances and fidelity between states from the point of view of information theory and we will end with a little introduction to the notions of relativistic quantum information. -
Quantum Fields and Strings 2021/2022
This course covers three distinct topics: conformal field theory, anomalies, and string theory. The conformal field theory section of the course introduces conformal transformation and the conformal algebra, n-point functions in CFTs, and OPEs. The anomalies portion of the course focuses on the functional integral derivation of the chiral anomaly. The string theory part of the course derives the bosonic string spectrum and introduces T-duality and D-branes. -
Geometry and Topology for Physicists 2021/2022
The aim of this course is to introduce concepts in topology and geometry for applications in theoretical physics. The topics will be chosen depending on time availability from the following list: topological manifolds and smooth manifolds, differential forms and integration on manifolds, Lie groups and Lie algebras, and Riemann surfaces, cohomology and the fundamental group. -
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PSI Lecture - Condensed Matter
PSI Lecture - Condensed Matter -
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Quantum Field Theory for Cosmology
Quantum Field Theory for Cosmology -
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Special Topics in Astrophysics - Numerical Hydrodynamics
Special Topics in Astrophysics - Numerical Hydrodynamics -
Summer Undergrad 2020 - Numerical Methods
This course has two main goals: (1) to introduce some key models from condensed matter physics; and (2) to introduce some numerical approaches to studying these (and other) models. As a precursor to these objectives, we will carefully understand many-body states and operators from the perspective of condensed matter theory. (However, I will cover only spin models. We will not discuss or use second quantization.)
Once this background is established, we will study the method of exact diagonalization and write simple python programs to find ground states, correlation functions, energy gaps, and other properties of the transverse-field Ising model. We will also discuss the computational limitations of exact diagonalization. Finally, I will introduce the concept of matrix product states, and we will see that these can be used to study ground state properties for much larger systems than can be studied with exact diagonalization.
Each 90-minute session will include substantial programming exercises in addition to lecture. Prior programming experience is not expected or required, but I would like everyone to have python (version 3) installed on their computer prior to the first class, including Jupyter notebooks; see “Resources” below.