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	nombre	tiempo	vistas
	18. Differntial Algebraic Equations 2	55:27	69
	30. Models vs. Data 3	50:32	50
	8. Quasi-Newton-Raphson Methods	51:23	125
	34. Stochastic Chemical Kinetics 1	53:57	39
	21. Boundary Value Problems 2	54:25	32
	22. Partial Differential Equations 1	49:34	130
	28. Models vs. Data 1	54:19	57
	7. Solutions of Nonlinear Equations; Newton-Raphson Method	45:17	156
	27. Probability Theory 2	53:12	82
	36. Final Lecture	46:00	24
	35. Stochastic Chemical Kinetics 2	47:32	20
	9. Homotopy and Bifurcation	53:24	80
	6. Singular Value Decomposition; Iterative Solutions of Linear Equations	47:12	274
	33. Monte Carlo Methods 2	50:21	143
	26. Partial Differential Equations 2	51:12	53
	25. Review Session	56:10	30
	20. Boundary Value Problem 1	51:32	42
	Scenario 11: Ecosystem Services Analysis	6:19	36
	Scenario 7: Local vs. Expert Knowledge - Student Presentation	5:58	100
	Scenario 9: Cost-Benefit Analysis - Class Discussion	12:41	21
	Scenario 4: Comparative Policy Analysis	6:16	13
	Scenario 10: Societal Risk Assessment	5:36	18
	Scenario 6: Sustainable Development	5:45	19
	Scenario 2: The Policy-Making Process	6:40	36
	Scenario 8: Environmental Impact Assessment	6:30	19
	Scenario 14: Relying on Effective Dispute Resolution	5:50	11
	Scenario 13: Building an Informed Consensus	5:30	18
	Scenario 9: Cost-Benefit Analysis - Cold Call	6:40	25
	Scenario 9: Cost-Benefit Analysis - Student Presentation	5:35	10
	Scenario 12: Public Participation Techniques and Strategies	5:55	12
	Scenario 3: Policy Evaluation	6:18	17
	Scenario 5: Environmental Ethics & the Precautionary Principle	9:37	13
	Scenario 7: Local Knowledge vs. Expert Knowledge - Cold Call	6:13	14
	Instructor Interview: Using Visual Materials to Teach 21st Century Skills	2:47	312
	Instructor Interview: Meet the Educator	1:16	266
	Instructor Interview: MIT OpenCourseWare / A Bold Idea	6:15	208
	Instructor Interview: Flipping the Classroom "Changing Everything"	5:26	120
	Instructor Interview: A Major Course Goal / Learning to Work in Teams	1:55	102
	Instructor Interview: Collaborating with Guest Lecturers	1:17	42
	Instructor Interview: Transforming Residential Education with Open Digital Content	2:21	80
	Instructor Interview: On Visualizing Cultures	5:46	105
	11. Lifecycle Management	1:46:32	117
	6. Design Definition and Multidisciplinary Optimization	1:30:42	233
	3. Systems Modeling Languages	1:41:38	396
	7. Miscellaneous Topics — MBSE and Introduction to CAD (Guest Lecture from Solidworks)	1:35:45	75
	2. Requirements Definition	1:39:52	460
	10. Commissioning and Operations	1:08:38	77
	8. Systems Integration and Interface Management	1:30:10	105
	9. Verification and Validation	1:37:49	94
	4. System Architecture and Concept Generation	46:10	157
	5. Concept Selection and Tradespace Exploration	1:43:39	106
	Assessing Student Work Completed as Teams	2:38	80
	Learning from CanSat Examples	2:17	93
	Online Written and Oral Exams	4:46	74
	Team Charters	1:29	69
	Reflective Memos	1:10	59
	Teaching the Class as a Small Private Online Course (SPOC)	3:46	196
	Course Design and Orienting Students with the "V Model"	2:25	348
	Teaching with Concept Questions	3:50	71
	Engaging Students in the Design Process through the CanSat Competition	3:17	127
	Meet the Educator	1:22	812
	Ideal Team Size for the CanSat Competition	1:44	86
	1. The Importance of Chemical Principles	21:19	2,987
	Clicker Competitions	4:00	247
	Promoting Active Participation During Lectures	3:51	197
	Building a Team of Teaching Assistants	3:50	125
	Preparing for Lectures	1:55	240
	Spotlighting Contemporary Chemists	2:50	98
	Using Humor to Engage Students	4:00	330
	5.111: A Space to Discover Your Passion for Chemistry	4:16	143
	Meet the Educator	3:21	265
	19. Chemical Equilibrium: Le Châtelier’s Principle	47:50	291
	Pizza Forums: Connecting with Students	2:24	49
	28. Transition Metals: Crystal Field Theory Part I	53:35	413
	12. The Shapes of Molecules: VSEPR Theory	45:18	551
	14. Valence Bond Theory and Hybridization	56:46	497
	27. Introduction to Transition Metals	43:31	227
	10. Lewis Structures	43:38	336
	33. Kinetics and Temperature	51:39	159
	20. Solubility and Acid-Base Equilibrium	42:11	124
	16. Thermodynamics: Gibbs Free Energy and Entropy	32:10	380
	11. Formal Charge and Resonance	28:46	242
	32. Kinetics: Reaction Mechanisms	46:28	116
	22. Acid-Base Equilibrium: Salt Solutions and Buffers	50:29	73
	4. Wave-Particle Duality of Matter; Schrödinger Equation	46:30	1,631
	26. Chemical and Biological Oxidations	43:50	69
	7. Multielectron Atoms	35:56	375
	13. Molecular Orbital Theory	1:05:37	509
	31. Nuclear Chemistry and Chemical Kinetics	34:41	130
	15. Thermodynamics: Bond and Reaction Enthalpies	38:21	270
	8. The Periodic Table and Periodic Trends	41:36	344
	18. Introduction to Chemical Equilibrium	47:51	190
	3. Wave-Particle Duality of Light	45:52	1,091
	24. Acid-Base Titrations Part II	20:53	50
	23. Acid-Base Titrations Part I	45:22	97
	30. Kinetics: Rate Laws	45:26	108
	35. Applying Chemical Principles	33:50	87
	9. Periodic Table; Ionic and Covalent Bonds	53:53	242
	6. Hydrogen Atom Wavefunctions (Orbitals)	1:00:39	508
	17. Thermodynamics: Now What Happens When You Heat It Up?	32:35	141
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MIT OpenCourseWare 5,896 vídeos, +2,320,000 suscriptores

MIT OpenCourseWare
5,896 vídeos, +2,320,000 suscriptores