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	nom	durée	vues
	L14.2 Quantization of the magnetic field on a torus	25:15	1 487
	L4.1 Scales and zeroth-order spectrum	25:51	1 430
	L9.1 The interaction picture and time evolution	26:34	1 501
	L23.4 Symmetric and Antisymmetric states of N particles	11:35	775
	L21.2 Phase shifts and impact parameter	27:39	801
	L17.3 Properties of Berry's phase	11:13	1 239
	L21.1 General computation of the phase shifts	18:15	849
	L18.2 Effective nuclear Hamiltonian. Electronic Berry connection	20:30	713
	L2.4 Degenerate Perturbation Theory: Leading energy corrections	6:52	1 916
	L6.1 Zeeman effect and fine structure	13:70	6 533
	L5.2 Interpretation of the Darwin correction from nonlocality	21:47	1 155
	L6.3 Weak-field Zeeman effect; the projection lemma	19:10	1 326
	L8.4 Deriving the connection formulae (continued) logical arrows	14:45	660
	L14.4 Landau levels (continued). Finite sample	9:80	966
	L3.1 Remarks on a 'good basis'	17:39	1 776
	L10.3 Integrating over the continuum to find Fermi's Golden Rule	19:38	1 393
	L1.2 Setting up the perturbative equations	16:90	7 578
	L20.2 The one-dimensional analogy for phase shifts	16:58	899
	L5.5 Assembling the fine-structure corrections	15:23	892
	L19.3 Differential and total cross section	20:21	3 096
	L18.3 Example: The hydrogen molecule ion	27:20	746
	L10.4 Autoionization transitions	11:31	626
	L7.1 The WKB approximation scheme	22:51	3 010
	L11.1 Harmonic transitions between discrete states	15:13	709
	L4.4 Dirac equation for the electron and hydrogen Hamiltonian	15:10	6 752
	L5.4 Spin-orbit correction	8:32	1 409
	L15.4 Instantaneous energy eigenstates and Schrodinger equation	26:47	730
	L24.4 The symmetrization postulate (continued)	20:51	1 159
	L6.4 Strong-field Zeeman	9:50	1 058
	L22.3 Diagrammatic representation of the Born series. Scattering amplitude for spherically symm...	21:42	728
	L20.1 Review of scattering concepts developed so far	9:30	972
	L23.1 Permutation operators and projectors for two particles	22:23	640
	L10.1 Box regularization: density of states for the continuum	20:32	1 139
	L21.3 Integral equation for scattering and Green's function	30:27	1 953
	L13.5 Charged particles in EM fields: Schrodinger equation	8:39	883
	L3.4 Degeneracy resolved to second order (continued)	11:36	863
	L5.1 Evaluating the Darwin correction	12:51	1 430
	L7.2 Approximate WKB solutions	19:20	1 187
	L1.3 Calculating the energy corrections	6:27	4 510
	L14.3 Particle in a constant magnetic field: Landau levels	18:20	1 953
	L16.2 Analysis with an orthonormal basis of instantaneous energy eigenstates	14:32	665
	L12.3 Einstein's argument: the need for spontaneous emission	19:32	706
	L15.3 Phase space and intuition for quantum adiabatic invariants	16:24	721
	L24.1 Symmetrizer and antisymmetrizer for N particles	16:50	619
	L15.1 Classical analog: oscillator with slowly varying frequency	16:35	724
	L3.2 Degeneracy resolved to first order; state and energy corrections	29:12	1 681
	L16.1 Quantum adiabatic theorem stated	13:30	1 662
	L23.2 Permutation operators acting on operators	11:45	497
	L4.3 The Pauli equation for the electron in an electromagnetic field	18:12	2 067
	L20.3 Scattering amplitude in terms of phase shifts	15:00	1 084
	L22.4 Identical particles and exchange degeneracy	19:42	1 402
	L11.2 Transition rates for stimulated emission and absorption processes	17:13	756
	L11.3 Ionization of hydrogen: conditions of validity, initial and final states	20:55	653
	L12.4 Einstein's argument: B and A coefficients	9:43	543
	L20.5 Identification of phase shifts. Example: hard sphere	18:20	888
	L12.1 Ionization rate for hydrogen: final result	16:24	508
	L20.4 Cross section in terms of partial cross sections. Optical theorem	13:14	994
	L16.4 Landau-Zener transitions	19:31	1 044
	L18.1 Born-Oppenheimer approximation: Hamiltonian and electronic states	24:49	2 307
	L9.4 Setting up perturbation theory	6:36	787
	L8.2 Asymptotic expansions of Airy functions	19:38	915
	L2.2 Anharmonic Oscillator via a quartic perturbation	20:56	3 168
	L24.2 Symmetrizer and antisymmetrizer for N particles (continued)	24:55	615
	L7.3 Validity of the WKB approximation	17:10	1 162
	L17.2 Berry's phase and Berry's connection	25:50	2 744
	L9.3 Example: Instantaneous transitions in a two-level system	29:25	888
	L22.1 Setting up the Born Series	21:80	846
	L17.1 Configuration space for Hamiltonians	15:28	1 454
	L12.2 Light and atoms with two levels, qualitative analysis	14:32	536
	L8.3 Deriving the connection formulae	22:32	659
	L5.3 The relativistic correction	19:16	1 529
	L6.2 Weak-field Zeeman effect; general structure	10:90	1 647
	L15.2 Classical adiabatic invariant	15:80	798
	L13.4 Charged particles in EM fields: potentials and gauge invariance	21:51	1 300
	L13.2 Transition rates induced by thermal radiation (continued)	16:36	444
	L13.3 Einstein's B and A coefficients determined. Lifetimes and selection rules	13:55	726
	L23.3 Permutation operators on N particles and transpositions	29:40	627
	28. Modern Electronic Structure Theory: Basis Sets	50:60	6 297
	36. Time Dependence of Two-Level Systems: Density Matrix, Rotating Wave Approximation	48:41	3 438
	9. The Harmonic Oscillator: Creation and Annihilation Operators	48:14	2 434
	8. Quantum Mechanical Harmonic Oscillator	52:28	2 678
	20. Hydrogen Atom I	48:57	3 614
	34. Chirped Pulse Microwave: Free Induction Decay, Bloch Visualization	50:27	236
	26. Qualitative MO Theory: Hückel	52:48	803
	17. Rigid Rotor I; Orbital Angular Momentum	51:29	1 593
	29. Modern Electronic Structure Theory: Electronic Correlation	52:13	1 522
	32. Intermolecular Interactions by Non-Degenerate Perturbation Theory	54:30	802
	31. Time-Dependent Perturbation Theory II: H is Time-Dependent: Two-Level Problem	52:45	918
	25. Molecular Orbital Theory II; H2+, A2, AB Diatomics	53:60	831
	3. Two-Slit Experiment; Quantum Weirdness	50:58	4 321
	5. Quantum Mechanics: Free Particle and Particle in 1D Box	54:39	3 348
	7. Classical Mechanical Harmonic Oscillator	51:11	1 609
	13. From Hij Integrals to H Matrices I	54:36	972
	19. Spectroscopy: Probing Molecules with Light	50:37	1 190
	10. The Time-Dependent Schrödinger Equation	52:23	1 747
	21. Hydrogen Atom II; Rydberg States	52:42	835
	22. Helium Atom	52:41	1 420
	23. Many-Electron Atoms	51:60	861
	2. Wave Nature of the Electron and the Internal Structure of an Atom	45:16	6 767
	11. Wavepacket Dynamics for Harmonic Oscillator and PIB	54:59	152
précédent 1 2 3 4 5 6 7 8 9 10 11 suivant [+10]

MIT OpenCourseWare 5 896 vidéos, +2 320 000 abonnés

MIT OpenCourseWare
5 896 vidéos, +2 320 000 abonnés