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| | tiempo | vistas | |
| 21. Acid-Base Equilibrium: Is MIT Water Safe to Drink? | 1:00:22 | 86 | |
| 34. Kinetics: Catalysts | 41:14 | 69 | |
| 5. Hydrogen Atom Energy Levels | 41:39 | 543 | |
| 29. Transition Metals: Crystal Field Theory Part II | 35:60 | 146 | |
| 2. Atomic Structure | 39:00 | 1,649 | |
| 25. Oxidation-Reduction and Electrochemical Cells | 53:80 | 104 | |
| L13.1 Delta function potential I: Preliminaries. | 16:40 | 413 | |
| L6.3 Probability current and current conservation. | 15:20 | 368 | |
| L8.3 Three-dimensional Fourier transforms. | 6:40 | 346 | |
| L6.4 Three dimensional current and conservation. | 18:11 | 321 | |
| L10.5 Solving particle on a circle. | 11:50 | 270 | |
| L12.3 Qualitative insights: Local de Broglie wavelength. | 15:51 | 116 | |
| L7.3 Widths and uncertainties. | 19:12 | 193 | |
| L8.2 Parseval identity. | 15:49 | 223 | |
| L4.1 de Broglie wavelength in different frames. | 14:53 | 537 | |
| L6.2 Is probability conserved? Hermiticity of the Hamiltonian. | 20:40 | 271 | |
| L7.1 Wavepackets and Fourier representation. | 11:14 | 296 | |
| L10.1 Uncertainty and eigenstates. | 15:52 | 164 | |
| L12.4 Correspondence principle: amplitude as a function of position. | 5:54 | 88 | |
| L13.2 Delta function potential I: Solving for the bound state. | 15:21 | 103 | |
| L5.2 Free Schrödinger equation. | 9:56 | 547 | |
| L8.1 Fourier transforms and delta functions. | 13:57 | 252 | |
| L7.2 Reality condition in Fourier transforms. | 9:90 | 205 | |
| L12.2 Potentials that satisfy V(-x) = V(x). | 14:18 | 102 | |
| L11.4 Finite square well. Setting up the problem. | 22:30 | 129 | |
| L13.3 Node Theorem. | 13:10 | 101 | |
| L10.3 Expectation values on stationary states. | 9:00 | 94 | |
| L9.2 Eigenfunctions of a Hermitian operator. | 13:60 | 162 | |
| L4.6 The wave for a free particle. | 14:33 | 349 | |
| L14.1 Recursion relation for the solution. | 12:26 | 61 | |
| L5.5 Interpretation of the wavefunction. | 7:57 | 268 | |
| L5.4 Commutators, matrices, and 3-dimensional Schrödinger equation. | 16:13 | 289 | |
| L10.4 Comments on the spectrum and continuity conditions. | 13:10 | 78 | |
| L4.4 Group velocity and stationary phase approximation. | 10:32 | 371 | |
| L7.5 Time evolution of a free particle wavepacket. | 9:44 | 158 | |
| L8.5 Time dependence of expectation values | 7:38 | 143 | |
| L11.5 Finite square well energy eigenstates. | 10:39 | 97 | |
| L14.4 Ground state wavefunction. | 15:57 | 63 | |
| L13.4 Harmonic oscillator: Differential equation. | 16:42 | 116 | |
| L12.5 Local picture of the wavefunction. | 12:52 | 75 | |
| L4.3 The frequency of a matter wave. | 10:23 | 422 | |
| L11.2 Infinite square well energy eigenstates. | 13:13 | 95 | |
| L10.2 Stationary states: key equations. | 18:42 | 123 | |
| L4.5 Motion of a wave-packet. | 8:59 | 308 | |
| L9.4 Consistency condition. Particle on a circle. | 17:45 | 131 | |
| L14.2 Quantization of the energy. | 23:19 | 58 | |
| L13.5 Behavior of the differential equation. | 10:31 | 82 | |
| L9.5 Defining uncertainty. | 10:31 | 121 | |
| L9.3 Completeness of eigenvectors and measurement postulate. | 16:56 | 149 | |
| L9.1 Expectation value of Hermitian operators. | 16:40 | 181 | |
| L6.1 Normalizable wavefunctions and the question of time evolution. | 16:49 | 287 | |
| L12.1 Nondegeneracy of bound states in 1D. Real solutions. | 12:35 | 96 | |
| L5.3 The general Schrödinger equation. x, p commutator. | 17:58 | 306 | |
| L8.4 Expectation values of operators. | 28:15 | 165 | |
| L7.4 Shape changes in a wave. | 16:56 | 165 | |
| L11.3 Nodes and symmetries of the infinite square well eigenstates. | 9:43 | 91 | |
| L11.1 Energy eigenstates for particle on a circle. | 16:12 | 133 | |
| L4.2 Galilean transformation of ordinary waves. | 12:16 | 444 | |
| L12.6 Energy eigenstates on a generic symmetric potential. Shooting method. | 15:27 | 81 | |
| L14.3 Algebraic solution of the harmonic oscillator. | 16:50 | 71 | |
| L5.1 Momentum operator, energy operator, and a differential equation. | 20:32 | 403 | |
| 1. Course Overview and Introduction | 1:08:19 | 15,482 | |
| 6. Independent Chip Model | 1:20:11 | 606 | |
| 4. Preflop Re-raising Theory | 1:17:40 | 621 | |
| 7. An In-depth Combinatorial Hand Analysis in Cash Games | 1:18:10 | 506 | |
| 2. Introduction to Postflop Play | 1:15:54 | 1,247 | |
| 3. Tournaments vs. Cash Games | 1:18:24 | 528 | |
| L1.1 Quantum mechanics as a framework. Defining linearity. | 17:49 | 21,535 | |
| L18.1 Incident packet and delay for reflection. | 18:52 | 669 | |
| L21.1 Associated Legendre functions and spherical harmonics. | 18:52 | 669 | |
| L12.2 Potentials that satisfy V(-x) = V(x). | 14:19 | 193 | |
| L1.5 The nature of superposition. Mach-Zehnder interferometer. | 14:31 | 5,524 | |
| L15.3 Creation and annihilation operators acting on energy eigenstates. | 21:40 | 269 | |
| L24.3 Hamiltonian and emerging spin angular momentum. | 15:43 | 268 | |
| L19.3 Modeling a resonance. | 15:38 | 281 | |
| L4.6 The wave for a free particle. | 14:35 | 222 | |
| L14.1 Recursion relation for the solution. | 12:26 | 98 | |
| L9.3 Completeness of eigenvectors and measurement postulate. | 16:57 | 143 | |
| L12.6 Energy eigenstates on a generic symmetric potential. Shooting method. | 15:26 | 91 | |
| L3.3 Compton Scattering. | 22:37 | 363 | |
| L11.2 Infinite square well energy eigenstates. | 13:16 | 51 | |
| L12.4 Correspondence principle: amplitude as a function of position. | 5:53 | 51 | |
| L16.2 Reflection and transmission coefficients. | 8:12 | 52 | |
| L22.1 Center of mass and relative motion wavefunctions. | 14:23 | 121 | |
| L14.2 Quantization of the energy. | 23:23 | 52 | |
| L3.1 The photoelectric effect. | 22:55 | 714 | |
| L13.5 Behavior of the differential equation. | 10:31 | 162 | |
| L20.4 Simultaneous eigenstates and quantization of angular momentum. | 24:36 | 60 | |
| L13.3 Node Theorem. | 13:10 | 138 | |
| L8.4 Expectation values of operators. | 28:16 | 106 | |
| L10.1 Uncertainty and eigenstates. | 15:53 | 65 | |
| L23.1 Energy levels and diagram for hydrogen. | 13:42 | 57 | |
| L10.4 Comments on the spectrum and continuity conditions. | 13:10 | 50 | |
| L14.3 Algebraic solution of the harmonic oscillator. | 16:51 | 87 | |
| L21.4 Hydrogen atom two-body problem. | 25:50 | 79 | |
| L9.1 Expectation value of Hermitian operators. | 16:41 | 85 | |
| L22.4 Series solution and quantization of the energy. | 14:22 | 65 | |
| L5.4 Commutators, matrices, and 3-dimensional Schrödinger equation. | 16:13 | 97 | |
| L4.4 Group velocity and stationary phase approximation. | 10:32 | 398 | |
| L19.5 Resonances in the complex k plane. | 15:15 | 35 | |
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