33:31

Working With Magnetic Moments Historical Review and The Electron Electron Interaction Part I

11:07

Working With Magnetic Moments Historical Review and The Electron Electron Interaction Part II

01:35:52

Do you speak Quantum Mechanics (Episode 5): Wave Functions and Continuous Representations

01:16:47

Do you speak Quantum Mechanics (Episode 4): Examples on the Use of Semantics of Quantum Mechanics

01:15:39

Multivariable Calculus: Partial Derivatives, The Chain Rule and Laplace equation

01:24:35

Communicating Science: Poster Design in Latex Overleaf Approaching Design From Jupyter Notebooks

01:01:34

Euler Lagrange Formalism of Calculus of Variations and Double Pendulum

46:21

Theory of Vector Fields Interpretation of The Gradient Divergence and Rotational

43:24

Gradient of a Scalar Field, Divergence and How to Plot A Vector Field in Jupyter Notebooks.

01:20:40

Electromagnetic Theory: Scalar Fields and Vector Fields in Jupyter Notebooks

01:24:57

Condensed Matter Seminar: Semiclassical Boltzman Approach To Charge and Heat Transport in Matter

39:59

Review Course on Quantum Dissipative Dynamics

01:11:57

Introduction to Numpy and Matplotlib With Jupyter (Python) - Numerical Analysis

37:14

Jupyter Notebooks Tutorial Part I: Getting Started with Numpy and Matplotlib (With Taylor Series)

01:47:26

Dissipative Quantum Dynamics - Lecture 17 (Klein Gordon Equation and Quantization of a Field Theory)

01:23:21

Dissipative Quantum Dynamics - Lecture 16 (Classical Field Theory and Unified Space Time Treatment)

01:26:50

Dissipative Quantum Dynamics Lecture 15 (Field Operator and Greens Function in Quantum Scattering)

01:35:03

Dissipative Quantum Dynamics Lecture 14 (Retarded Greens Function and Retarded Potentials)

01:49:24

Dissipative Quantum Dynamics Lecture 13 (Greens Function for Poisson Equation and Memory)

01:59:00

Dissipative Quantum Dynamics Lecture 12 (Conditions for Causality and Kramers Kronig Relations)

01:32:58

Quantum Dissipative Dynamcs Lecture 11 (Dissipation in The Lorentz Oscillator - Intro to Causality)

01:21:07

Quantum Dissipative Dynamics Lecture 10 (Biological Membranes, Dissipation and Lorentz Oscillators)

01:51:44

Quantum Dissipative Dynamics Lecture 9 (Langevin Dynamics and the Fluctuation Dissipation Relation)

01:43:20

Kinetic Theory and Statistical Mechanics Part III (Ensamble Average, Conservation and Equilibrium)

01:07:38

Kinetic Theory and Statistical Mechanics Part IV (Many Particle Density And Dynamics)

02:02:11

Quantum Dissipative Dynamics -Lecture 8(Random Walks, Fokker Planck Equations and Langevin Dynamics)

02:10:16

Quantum Dissipative Dynamics - Lecture 7 (Brownian Motion Dissipation and Damping From Green's Func)

02:08:25

Quantum Dissipative Dynamics -Lecture 6 (Open Quantum Systems and Spectral Density of the Reservoir)

01:45:44

Quantum Dissipative Dynamics - Lesson II (Plane Wave Basis and The State Operator in Position Basis)

01:39:21

Introduction To Statistical Mechanics - Lecture 5 (The Langevin Function and Curie's Law)

02:04:06

Introduction To Statistical Mechanics - Lecture 2 (Classical/Quantum Theory of Partition Functions)

02:05:13

Introduction To Statistical Mechanics - Lecture 1 (What is the Scope of Statistical Mechanics)

01:04:59

Introduction To Statistical Mechanics -Lecture 4 (Electrodynamic/Statistical Theory of Polarization)

42:31

Introduction To Statistical Mechanics - Lecture 3 (Statistical Mechanical Observables at Finite T)

01:37:10

Quantum Dissipative Dynamics -Lesson I (Quantum Statistical Mechanics of the Heisenberg Hamiltonian)

01:36:31

Quantum Dissipative Dynamics Lecture 5 (Quantum Statistical Mechanics From The State Operator)

02:05:02

Series of Seminars: Do You Speak Quantum Mechanics - Episode 3 (Quantum Coherence and Information)

01:49:12

Series of Seminars: Do You Speak Quantum Mechanics? -Episode 2(Hilbert Spaces and Two Level Systems)

01:57:09

Series of Seminars: Do You Speak Quantum Mechanics? Episode 1 (Formal Structure and Vector Spaces)

02:46:46

Quantum Dissipative Dynamics - Lecture 4 (NonUnitary Evolution and Lindblad Quantum Master Equation)

01:45:46

Quantum Dissipative Dynamics Lecture 3 (Quantum Resources: Entanglement and Coherence)

01:09:17

Quantum Dissipative Dynamics Lecture 1 (Research Unit on Nonequilibrium Quantum Physical Chemistry)

51:56

Quantum Dissipative Dynamics Lecture 2 (Introducing Mathematical Methods for Evaluating Dynamics)

58:18

Problems in Quantum Mechanics: Modeling The Hydrogen Molecule in Matrix Representations

01:43:20

Kinetic Theory and Statistical Mechanics Part III: Ensemble Average/ Equilibrium Phase Space Density

01:07:38

Kinetic Theory and Statistical Mechanics Part IV: Many Particle Phase Space Density And Dynamics

01:59:57

Foundations of Electrostatics in Matter - Lecture I : The Origin of Electric Charge.

01:02:53

Kinetic Theory and Statistical Mechanics Part II: Phase Space Density vs State (Density) Operator

02:05:33

Kinetic Theory and Statistical Mechanics Part I: Intro, Liouville's Theorem and Phase Space Density

01:29:56

Differential Equations in Science and Engineering: Theory of Laplace Transforms Part II

01:07:58

Differential Equations in Science and Engineering: Theory of Laplace Transforms Part I

02:42:00

Introduction to Numpy and To Sympy Differential Equation

51:45

Mathematical Requirements for Quantum Mechanics: Contents, Introduction And Euclidean Vector Spaces

01:29:10

Advanced Theoretical Mechanics: Classical Field Theory and The Structure of Space Time

01:23:52

Advanced Theoretical Mechanics: Introduction to Classical Field Theory - Variational Calc for Fields

01:14:29

Adiabatic Quantum Mechanics Topology in Condensed Matter: The Phenomenon of Superconductivity

01:23:52

Advanced Theoretical Mechanics: Introduction to Classical Lagrangian Field Theory Part I

01:17:07

Linear Algebra in Science and Engineering: Workshop on Linear Systems and Pauli Matrices

01:00:04

Linear Algebra in Science and Engineering: Applications of Systems of Equations to Circuit Theory

01:11:18

Linear Algebra For Science and Engineering: Exercise Set I - Matrices, Inverse and Determinants