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5.68J Kinetics of Chemical Reactions (MIT) 5.68J Kinetics of Chemical Reactions (MIT)

Description

This course deals with the experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry. This course deals with the experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.

Subjects

quantum mechanics | quantum mechanics | statistical mechanics | statistical mechanics | chemical reaction kinetics | chemical reaction kinetics | transition-state theories | transition-state theories | molecular beam scattering | molecular beam scattering | classical techniques | classical techniques | rate constants | rate constants | pressure-dependence | pressure-dependence | chemical activation | chemical activation | atmosphere | atmosphere | combustion | combustion | catalytic | catalytic | biological chemistry | biological chemistry | elementary kinetics | elementary kinetics | experimental kinetics | experimental kinetics | reaction rate theory | reaction rate theory | thermodynamics | thermodynamics | practical prediction methods | practical prediction methods | handling large kinetic models | handling large kinetic models | reactions in solution | reactions in solution | catalysis | catalysis | 5.68 | 5.68 | 10.652 | 10.652

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10.442 Biochemical Engineering (MIT) 10.442 Biochemical Engineering (MIT)

Description

This course focuses on the interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems are featured among lecture topics. Kinetics of growth, death, and metabolism are also covered. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, and enzyme technology round out the subject material. This course focuses on the interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems are featured among lecture topics. Kinetics of growth, death, and metabolism are also covered. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, and enzyme technology round out the subject material.

Subjects

chemical engineering | chemical engineering | biochemistry | biochemistry | microbiology | microbiology | mathematical representations of microbial systems | mathematical representations of microbial systems | kinetics of growth | kinetics of growth | kinetics of death | kinetics of death | kinetics of metabolism | kinetics of metabolism | continuous fermentation | continuous fermentation | agitation | agitation | mass transfer | mass transfer | scale-up in fermentation systems | scale-up in fermentation systems | enzyme technology | enzyme technology

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20.320 Analysis of Biomolecular and Cellular Systems (MIT) 20.320 Analysis of Biomolecular and Cellular Systems (MIT)

Description

This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling. This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

Subjects

biological engineering | biological engineering | kinase | kinase | PyMOL | PyMOL | PyRosetta | PyRosetta | MATLAB | MATLAB | Michaelis-Menten | Michaelis-Menten | bioreactor | bioreactor | bromodomain | bromodomain | protein-ligand interactions | protein-ligand interactions | titration analysis | titration analysis | fractional separation | fractional separation | isothermal titration calorimetry | isothermal titration calorimetry | ITC | ITC | mass spectrometry | mass spectrometry | MS | MS | co-immunoprecipitation | co-immunoprecipitation | Co-IP | Co-IP | Forster resonance energy transfer | Forster resonance energy transfer | FRET | FRET | primary ligation assay | primary ligation assay | PLA | PLA | surface plasmon resonance | surface plasmon resonance | SPR | SPR | enzyme kinetics | enzyme kinetics | kinase engineering | kinase engineering | competitive inhibition | competitive inhibition | epidermal growth factor receptor | epidermal growth factor receptor | mitogen-activated protein kinase | mitogen-activated protein kinase | MAPK | MAPK | genome editing | genome editing | Imatinib | Imatinib | Gleevec | Gleevec | Glivec | Glivec | drug delivery | drug delivery | kinetics of molecular processes | kinetics of molecular processes | dynamics of molecular processes | dynamics of molecular processes | kinetics of cellular processes | kinetics of cellular processes | dynamics of cellular processes | dynamics of cellular processes | intracellular scale | intracellular scale | extracellular scale | extracellular scale | and cell population scale | and cell population scale | biotechnology applications | biotechnology applications | gene regulation networks | gene regulation networks | nucleic acid hybridization | nucleic acid hybridization | signal transduction pathways | signal transduction pathways | cell populations in tissues | cell populations in tissues | cell populations in bioreactors | cell populations in bioreactors | experimental methods | experimental methods | quantitative analysis | quantitative analysis | computational modeling | computational modeling

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20.320 Biomolecular Kinetics and Cell Dynamics (MIT) 20.320 Biomolecular Kinetics and Cell Dynamics (MIT)

Description

This class covers analysis of kinetics and dynamics of molecular and cellular processes across a hierarchy of scales, including intracellular, extracellular, and cell population levels; a spectrum of biotechnology applications are also taken into consideration. Topics include gene regulation networks; nucleic acid hybridization; signal transduction pathways; and cell populations in tissues and bioreactors. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling. This class covers analysis of kinetics and dynamics of molecular and cellular processes across a hierarchy of scales, including intracellular, extracellular, and cell population levels; a spectrum of biotechnology applications are also taken into consideration. Topics include gene regulation networks; nucleic acid hybridization; signal transduction pathways; and cell populations in tissues and bioreactors. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

Subjects

kinetics of molecular processes | kinetics of molecular processes | dynamics of molecular processes | dynamics of molecular processes | kinetics of cellular processes | kinetics of cellular processes | dynamics of cellular processes | dynamics of cellular processes | intracellular scale | intracellular scale | extracellular scale | extracellular scale | and cell population scale | and cell population scale | biotechnology applications | biotechnology applications | gene regulation networks | gene regulation networks | nucleic acid hybridization | nucleic acid hybridization | signal transduction pathways | signal transduction pathways | cell populations in tissues | cell populations in tissues | cell populations in bioreactors | cell populations in bioreactors | experimental methods | experimental methods | quantitative analysis | quantitative analysis | computational modeling | computational modeling | cell population scale | cell population scale

License

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5.68J Kinetics of Chemical Reactions (MIT)

Description

This course deals with the experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.

Subjects

quantum mechanics | statistical mechanics | chemical reaction kinetics | transition-state theories | molecular beam scattering | classical techniques | rate constants | pressure-dependence | chemical activation | atmosphere | combustion | catalytic | biological chemistry | elementary kinetics | experimental kinetics | reaction rate theory | thermodynamics | practical prediction methods | handling large kinetic models | reactions in solution | catalysis | 5.68 | 10.652

License

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20.320 Analysis of Biomolecular and Cellular Systems (MIT)

Description

This course focuses on computational and experimental analysis of biological systems across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. The two central themes of the course are modeling of complex dynamic systems and protein design and engineering. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis is placed on experimental methods, quantitative analysis, and computational modeling.

Subjects

biological engineering | kinase | PyMOL | PyRosetta | MATLAB | Michaelis-Menten | bioreactor | bromodomain | protein-ligand interactions | titration analysis | fractional separation | isothermal titration calorimetry | ITC | mass spectrometry | MS | co-immunoprecipitation | Co-IP | Forster resonance energy transfer | FRET | primary ligation assay | PLA | surface plasmon resonance | SPR | enzyme kinetics | kinase engineering | competitive inhibition | epidermal growth factor receptor | mitogen-activated protein kinase | MAPK | genome editing | Imatinib | Gleevec | Glivec | drug delivery | kinetics of molecular processes | dynamics of molecular processes | kinetics of cellular processes | dynamics of cellular processes | intracellular scale | extracellular scale | and cell population scale | biotechnology applications | gene regulation networks | nucleic acid hybridization | signal transduction pathways | cell populations in tissues | cell populations in bioreactors | experimental methods | quantitative analysis | computational modeling

License

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10.442 Biochemical Engineering (MIT)

Description

This course focuses on the interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems are featured among lecture topics. Kinetics of growth, death, and metabolism are also covered. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, and enzyme technology round out the subject material.

Subjects

chemical engineering | biochemistry | microbiology | mathematical representations of microbial systems | kinetics of growth | kinetics of death | kinetics of metabolism | continuous fermentation | agitation | mass transfer | scale-up in fermentation systems | enzyme technology

License

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5.68J Kinetics of Chemical Reactions (MIT)

Description

This course deals with the experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.

Subjects

quantum mechanics | statistical mechanics | chemical reaction kinetics | transition-state theories | molecular beam scattering | classical techniques | rate constants | pressure-dependence | chemical activation | atmosphere | combustion | catalytic | biological chemistry | elementary kinetics | experimental kinetics | reaction rate theory | thermodynamics | practical prediction methods | handling large kinetic models | reactions in solution | catalysis | 5.68 | 10.652

License

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Chemistry for Biomedical Engineering Chemistry for Biomedical Engineering

Description

This course summarizes the main aspects of Chemistry for Biomedical Engineers This course summarizes the main aspects of Chemistry for Biomedical Engineers

Subjects

a Biomdica | a Biomdica | Molecules | Molecules | Elementary thermodynamics | Elementary thermodynamics | Quimica Analitica | Quimica Analitica | Quimica Inorganica | Quimica Inorganica | Atoms | Atoms | Quimica Fisica | Quimica Fisica | Quimica Organica | Quimica Organica | States of Matter | States of Matter | Equilibrium Reactions | Equilibrium Reactions | Chemical kinetics | Chemical kinetics | 2012 | 2012

License

Copyright 2015, UC3M http://creativecommons.org/licenses/by-nc-sa/4.0/

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22.05 Neutron Science and Reactor Physics (MIT) 22.05 Neutron Science and Reactor Physics (MIT)

Description

This course introduces fundamental properties of the neutron. It covers reactions induced by neutrons, nuclear fission, slowing down of neutrons in infinite media, diffusion theory, the few-group approximation, point kinetics, and fission-product poisoning. We emphasize the nuclear physics basis of reactor design and its relationship to reactor engineering problems. This course introduces fundamental properties of the neutron. It covers reactions induced by neutrons, nuclear fission, slowing down of neutrons in infinite media, diffusion theory, the few-group approximation, point kinetics, and fission-product poisoning. We emphasize the nuclear physics basis of reactor design and its relationship to reactor engineering problems.

Subjects

reactor physics | reactor physics | reactor layout | reactor layout | binding energy | binding energy | fission | fission | neutron cross-sections | neutron cross-sections | liquid drop model | liquid drop model | neutron life cycle | neutron life cycle | criticality | criticality | accidents | accidents | neutron flux | neutron flux | neutron current | neutron current | neutron diffusion theory | neutron diffusion theory | elastic neutron scattering | elastic neutron scattering | group diffusion method | group diffusion method | subcritical multiplication | subcritical multiplication | point kinetics | point kinetics | dynamic period equation | dynamic period equation | inhour equation | inhour equation | shutdown margin | shutdown margin

License

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7.89 Topics in Computational and Systems Biology (MIT) 7.89 Topics in Computational and Systems Biology (MIT)

Description

This is a seminar based on research literature. Papers covered are selected to illustrate important problems and approaches in the field of computational and systems biology, and provide students a framework from which to evaluate new developments. The MIT Initiative in Computational and Systems Biology (CSBi) is a campus-wide research and education program that links biology, engineering, and computer science in a multidisciplinary approach to the systematic analysis and modeling of complex biological phenomena. This course is one of a series of core subjects offered through the CSB PhD program, for students with an interest in interdisciplinary training and research in the area of computational and systems biology. Acknowledgments In addition to the staff listed on this page, the followi This is a seminar based on research literature. Papers covered are selected to illustrate important problems and approaches in the field of computational and systems biology, and provide students a framework from which to evaluate new developments. The MIT Initiative in Computational and Systems Biology (CSBi) is a campus-wide research and education program that links biology, engineering, and computer science in a multidisciplinary approach to the systematic analysis and modeling of complex biological phenomena. This course is one of a series of core subjects offered through the CSB PhD program, for students with an interest in interdisciplinary training and research in the area of computational and systems biology. Acknowledgments In addition to the staff listed on this page, the followi

Subjects

computational | computational | systems | systems | biology | biology | seminar | seminar | literature review | literature review | statistics | statistics | developmental | developmental | biochemistry | biochemistry | genetics | genetics | physics | physics | genomics | genomics | signal transduction | signal transduction | regulation | regulation | medicine | medicine | kinetics | kinetics | protein structure | protein structure | devices | devices | synthesis | synthesis | networks | networks | mapping | mapping

License

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3.14 Physical Metallurgy (MIT) 3.14 Physical Metallurgy (MIT)

Description

The central point of this course is to provide a physical basis that links the structure of metals with their properties. With this understanding in hand, the concepts of alloy design and microstructural engineering are also discussed, linking processing and thermodynamics to the structure and properties of metals. The central point of this course is to provide a physical basis that links the structure of metals with their properties. With this understanding in hand, the concepts of alloy design and microstructural engineering are also discussed, linking processing and thermodynamics to the structure and properties of metals.

Subjects

processing | structure | and properties of metals and alloys | processing | structure | and properties of metals and alloys | strength | stiffness | and ductility | strength | stiffness | and ductility | crystallography | defects | microstructure | crystallography | defects | microstructure | phase transformations | phase transformations | microstructural evolution | microstructural evolution | alloy thermodynamics and kinetics | alloy thermodynamics and kinetics | structural engineering alloys | structural engineering alloys | steel | steel | aluminum | aluminum

License

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5.111 Principles of Chemical Science (MIT) 5.111 Principles of Chemical Science (MIT)

Description

5.111 is an introductory chemistry course, emphasizing basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. This course also introduces the chemistry of biological, inorganic, and organic molecules. 5.111 is an introductory chemistry course, emphasizing basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. This course also introduces the chemistry of biological, inorganic, and organic molecules.

Subjects

introductory chemistry | introductory chemistry | atomic structure | atomic structure | molecular electronic structure | molecular electronic structure | thermodynamics | thermodynamics | acid-base equillibrium | acid-base equillibrium | redox | redox | chemical kinetics | chemical kinetics | catalysis | catalysis | lewis structures | lewis structures | VSEPR theory | VSEPR theory | acid-base equilibrium | acid-base equilibrium

License

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6.642 Continuum Electromechanics (MIT) 6.642 Continuum Electromechanics (MIT)

Description

This course focuses on laws, approximations, and relations of continuum electromechanics. Topics include mechanical and electromechanical transfer relations, statics and dynamics of electromechanical systems having a static equilibrium, electromechanical flows, and field coupling with thermal and molecular diffusion. See the syllabus section for a more detailed list of topics. This course focuses on laws, approximations, and relations of continuum electromechanics. Topics include mechanical and electromechanical transfer relations, statics and dynamics of electromechanical systems having a static equilibrium, electromechanical flows, and field coupling with thermal and molecular diffusion. See the syllabus section for a more detailed list of topics.

Subjects

continuum mechanics | continuum mechanics | electromechanics | electromechanics | mechanical and electromechanical transfer relations | mechanical and electromechanical transfer relations | statics | statics | dynamics | dynamics | electromechanical systems | electromechanical systems | static equililbrium | static equililbrium | electromechanical flows | electromechanical flows | field coupling | field coupling | thermal and molecular diffusion | thermal and molecular diffusion | electrokinetics | electrokinetics | streaming interactions | streaming interactions | materials processing | materials processing | magnetohydrodynamic and electrohydrodynamic pumps and generators | magnetohydrodynamic and electrohydrodynamic pumps and generators | ferrohydrodynamics | ferrohydrodynamics | physiochemical systems | physiochemical systems | heat transfer | heat transfer | continuum feedback control | continuum feedback control | electron beam devices | electron beam devices | plasma dynamics | plasma dynamics

License

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Kinetics (MIT) Kinetics (MIT)

Description

This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions.AcknowledgementsThe material for 5.60 has evolved over a period of many years, and therefore several faculty members have contributed to the development of the course contents. The following are known to have assisted in preparing the lecture notes available on OCW:Emeritus Professors of Chemistry: Robert A. Alberty, Carl W. Garland, Irwin Oppenheim, John S. Waugh.Professors of Chemistry: Moungi Bawendi, John M. Deutch, Robert W. Field, Robert G. Griffin, Keith A. Nelson, Robert J. Silbey, Jeffrey I. Steinfeld.Professor of Bioengineering and Computer Science: Bruce Tidor.Professor of Chemistry, Ri This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions.AcknowledgementsThe material for 5.60 has evolved over a period of many years, and therefore several faculty members have contributed to the development of the course contents. The following are known to have assisted in preparing the lecture notes available on OCW:Emeritus Professors of Chemistry: Robert A. Alberty, Carl W. Garland, Irwin Oppenheim, John S. Waugh.Professors of Chemistry: Moungi Bawendi, John M. Deutch, Robert W. Field, Robert G. Griffin, Keith A. Nelson, Robert J. Silbey, Jeffrey I. Steinfeld.Professor of Bioengineering and Computer Science: Bruce Tidor.Professor of Chemistry, Ri

Subjects

thermodynamics | thermodynamics | kinetics | kinetics | equilibrium | equilibrium | macroscopic systems | macroscopic systems | state variables | state variables | law of thermodynamics | law of thermodynamics | entropy | entropy | Gibbs function | Gibbs function | reaction rates | reaction rates | clapeyron | clapeyron | enthalpy | enthalpy | clausius | clausius | adiabatic | adiabatic | Hemholtz | Hemholtz | catalysis | catalysis | oscillators | oscillators | autocatalysis | autocatalysis | carnot cycle | carnot cycle

License

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7.88J Protein Folding Problem (MIT) 7.88J Protein Folding Problem (MIT)

Description

This course focuses on the mechanisms by which the amino acid sequence of polypeptide chains (proteins), determine their three-dimensional conformation. Topics in this course include sequence determinants of secondary structure, the folding of newly synthesized polypeptide chains within cells, folding intermediates aggregation and competing off-pathway reactions, and the unfolding and refolding of proteins in vitro. Additional topics covered are the role of helper proteins such as chaperonins and isomerases, protein recovery problems in the biotechnology industry, and diseases found associated with protein folding defects. This course focuses on the mechanisms by which the amino acid sequence of polypeptide chains (proteins), determine their three-dimensional conformation. Topics in this course include sequence determinants of secondary structure, the folding of newly synthesized polypeptide chains within cells, folding intermediates aggregation and competing off-pathway reactions, and the unfolding and refolding of proteins in vitro. Additional topics covered are the role of helper proteins such as chaperonins and isomerases, protein recovery problems in the biotechnology industry, and diseases found associated with protein folding defects.

Subjects

amino acid sequence | amino acid sequence | polypeptide chains | polypeptide chains | sequence determinants | sequence determinants | folding | folding | synthesized polypeptide chains within cells | synthesized polypeptide chains within cells | unfolding and refolding of proteins in vitro | unfolding and refolding of proteins in vitro | folding intermediates aggregation | folding intermediates aggregation | competing off-pathway reactions | competing off-pathway reactions | chaperonins | chaperonins | isomerases | isomerases | helper proteins | helper proteins | protein recovery problems | protein recovery problems | biotechnology industry | biotechnology industry | protein folding defects | protein folding defects | 3-D conformation | 3-D conformation | globular proteins | globular proteins | fibrous proteins | fibrous proteins | kinetics | kinetics | in vitro refolding | in vitro refolding | pathways | pathways | in vivo folding | in vivo folding | synthesized proteins | synthesized proteins | aggregation | aggregation | protein misfolding | protein misfolding | human disease | human disease | protein folding | protein folding | genome sequences | genome sequences | 7.88 | 7.88 | 5.48 | 5.48 | 7.24 | 7.24 | 10.543 | 10.543

License

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5.62 Physical Chemistry II (MIT) 5.62 Physical Chemistry II (MIT)

Description

This subject deals primarily with elementary statistical mechanics, transport properties, kinetic theory, solid state, reaction rate theory, and chemical reaction dynamics.AcknowledgementsThe lecture note materials for this course include contributions from Professor Sylvia T. Ceyer. The Staff for this course would like to acknowledge that these course materials include contributions from past instructors, textbooks, and other members of the MIT Chemistry Department affiliated with course #5.62. Since the following works have evolved over a period of many years, no single source can be attributed. This subject deals primarily with elementary statistical mechanics, transport properties, kinetic theory, solid state, reaction rate theory, and chemical reaction dynamics.AcknowledgementsThe lecture note materials for this course include contributions from Professor Sylvia T. Ceyer. The Staff for this course would like to acknowledge that these course materials include contributions from past instructors, textbooks, and other members of the MIT Chemistry Department affiliated with course #5.62. Since the following works have evolved over a period of many years, no single source can be attributed.

Subjects

physical chemistry | physical chemistry | partition functions | partition functions | atomic degrees of freedom | atomic degrees of freedom | molecular degrees of freedom | molecular degrees of freedom | chemical equilibrium | chemical equilibrium | thermodynamics | thermodynamics | intermolecular potentials | intermolecular potentials | equations of state | equations of state | solid state chemistry | solid state chemistry | einstein and debye solids | einstein and debye solids | kinetic theory | kinetic theory | rate theory | rate theory | chemical kinetics | chemical kinetics | transition state theory | transition state theory | RRKM theory | RRKM theory | collision theory | collision theory | equipartition | equipartition | fermi-dirac statistics | fermi-dirac statistics | boltzmann statistics | boltzmann statistics | bose-einstein statistics | bose-einstein statistics | statistical mechanics | statistical mechanics

License

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3.205 Thermodynamics and Kinetics of Materials (MIT) 3.205 Thermodynamics and Kinetics of Materials (MIT)

Description

This course explores materials and materials processes from the perspective of thermodynamics and kinetics. The thermodynamics aspect includes laws of thermodynamics, solution theory and equilibrium diagrams. The kinetics aspect includes diffusion, phase transformations, and the development of microstructure. This course explores materials and materials processes from the perspective of thermodynamics and kinetics. The thermodynamics aspect includes laws of thermodynamics, solution theory and equilibrium diagrams. The kinetics aspect includes diffusion, phase transformations, and the development of microstructure.

Subjects

Laws of thermodynamics | Laws of thermodynamics | solution theory | solution theory | equilibrium diagrams | equilibrium diagrams | kinetics of processes | kinetics of processes | diffusion | diffusion | phase transformations | phase transformations | microstructure development. | microstructure development. | microstructure development | microstructure development

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Kinetics (MIT) Kinetics (MIT)

Description

This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions.AcknowledgementsThe material for 5.60 has evolved over a period of many years, and therefore several faculty members have contributed to the development of the course contents. The following are known to have assisted in preparing the lecture notes available on OCW:Emeritus Professors of Chemistry: Robert A. Alberty, Carl W. Garland, Irwin Oppenheim, John S. Waugh.Professors of Chemistry: Moungi Bawendi, John M. Deutch, Robert W. Field, Robert G. Griffin, Keith A. Nelson, Robert J. Silbey, Jeffrey I. Steinfeld.Professor of Bioengineering and Computer Science: Bruce Tidor.Professor of Chem This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions.AcknowledgementsThe material for 5.60 has evolved over a period of many years, and therefore several faculty members have contributed to the development of the course contents. The following are known to have assisted in preparing the lecture notes available on OCW:Emeritus Professors of Chemistry: Robert A. Alberty, Carl W. Garland, Irwin Oppenheim, John S. Waugh.Professors of Chemistry: Moungi Bawendi, John M. Deutch, Robert W. Field, Robert G. Griffin, Keith A. Nelson, Robert J. Silbey, Jeffrey I. Steinfeld.Professor of Bioengineering and Computer Science: Bruce Tidor.Professor of Chem

Subjects

thermodynamics | thermodynamics | kinetics | kinetics | equilibrium | equilibrium | macroscopic systems | macroscopic systems | state variables | state variables | law of thermodynamics | law of thermodynamics | entropy | entropy | Gibbs function | Gibbs function | reaction rates | reaction rates

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BE.420J Biomolecular Kinetics and Cellular Dynamics (MIT) BE.420J Biomolecular Kinetics and Cellular Dynamics (MIT)

Description

This subject deals primarily with kinetic and equilibrium mathematical models of biomolecular interactions, as well as the application of these quantitative analyses to biological problems across a wide range of levels of organization, from individual molecular interactions to populations of cells. This subject deals primarily with kinetic and equilibrium mathematical models of biomolecular interactions, as well as the application of these quantitative analyses to biological problems across a wide range of levels of organization, from individual molecular interactions to populations of cells.

Subjects

receptor | receptor | ligand | ligand | signaling | signaling | enzyme | enzyme | binding | binding | hybridization | hybridization | cell | cell | dynamics | dynamics | metabolism | metabolism | regulation | regulation | kinetics | kinetics | BE.420 | BE.420 | 10.538J | 10.538J | 10.538 | 10.538

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17.462 Innovation in Military Organizations (MIT) 17.462 Innovation in Military Organizations (MIT)

Description

This seminar has three purposes. One, it inquires into the causes of military innovation by examining a number of the most outstanding historical cases. Two, it views military innovations through the lens of organization theory to develop generalizations about the innovation process within militaries. Three, it uses the empirical study of military innovations as a way to examine the strength and credibility of hypotheses that organization theorists have generated about innovation in non-military organizations. This seminar has three purposes. One, it inquires into the causes of military innovation by examining a number of the most outstanding historical cases. Two, it views military innovations through the lens of organization theory to develop generalizations about the innovation process within militaries. Three, it uses the empirical study of military innovations as a way to examine the strength and credibility of hypotheses that organization theorists have generated about innovation in non-military organizations.

Subjects

URIECA | URIECA | laboratory | laboratory | kinase | kinase | cancer cells | cancer cells | laboratory techniques | laboratory techniques | DNA | DNA | cultures | cultures | UV-Vis | UV-Vis | agarose gel | agarose gel | Abl-gleevec | Abl-gleevec | affinity tags | affinity tags | lyse | lyse | digest | digest | mutants | mutants | resistance | resistance | gel electrophoresis | gel electrophoresis | recombinant | recombinant | nickel affinity | nickel affinity | inhibitors | inhibitors | biochemistry | biochemistry | kinetics | kinetics | enzyme | enzyme | inhibition | inhibition | purification | purification | expression | expression | Political science | Political science | security studies | security studies | innovation | innovation | military organizations | military organizations | war | war | history | history | organization theory | organization theory | empirical study | empirical study | land warfare | land warfare | battleships | battleships | airpower | airpower | submarines | submarines | cruise | cruise | ballistic | ballistic | missiles | missiles | armor | armor | military affairs | military affairs | strategic | strategic | tactical | tactical | counterinsurgency | counterinsurgency | Vietnam | Vietnam | Revolution in Military Affairs | Revolution in Military Affairs | RMA | RMA

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3.091SC Introduction to Solid State Chemistry (MIT) 3.091SC Introduction to Solid State Chemistry (MIT)

Description

Introduction to Solid State Chemistry is a first-year single-semester college course on the principles of chemistry. This unique and popular course satisfies MIT's general chemistry degree requirement, with an emphasis on solid-state materials and their application to engineering systems. Introduction to Solid State Chemistry is a first-year single-semester college course on the principles of chemistry. This unique and popular course satisfies MIT's general chemistry degree requirement, with an emphasis on solid-state materials and their application to engineering systems.

Subjects

solid state chemistry | solid state chemistry | atomic structure | atomic structure | atomic bonding | atomic bonding | crystal structure | crystal structure | crystalline solid | crystalline solid | periodic table | periodic table | electron shell | electron shell | x-ray spectroscopy | x-ray spectroscopy | amorphous solid | amorphous solid | reaction kinetics | reaction kinetics | aqueous solution | aqueous solution | solid solution | solid solution | biomaterial | biomaterial | polymer | polymer | semiconductor | semiconductor | phase diagram | phase diagram | material processing | material processing

License

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6.642 Continuum Electromechanics (MIT) 6.642 Continuum Electromechanics (MIT)

Description

Includes audio/video content: AV faculty introductions. This course focuses on laws, approximations and relations of continuum electromechanics. Topics include mechanical and electromechanical transfer relations, statics and dynamics of electromechanical systems having a static equilibrium, electromechanical flows, and field coupling with thermal and molecular diffusion. Also covered are electrokinetics, streaming interactions, application to materials processing, magnetohydrodynamic and electrohydrodynamic pumps and generators, ferrohydrodynamics, physiochemical systems, heat transfer, continuum feedback control, electron beam devices, and plasma dynamics. Acknowledgements The instructor would like to thank Xuancheng Shao and Anyang Hou for transcribing into LaTeX the problem set solution Includes audio/video content: AV faculty introductions. This course focuses on laws, approximations and relations of continuum electromechanics. Topics include mechanical and electromechanical transfer relations, statics and dynamics of electromechanical systems having a static equilibrium, electromechanical flows, and field coupling with thermal and molecular diffusion. Also covered are electrokinetics, streaming interactions, application to materials processing, magnetohydrodynamic and electrohydrodynamic pumps and generators, ferrohydrodynamics, physiochemical systems, heat transfer, continuum feedback control, electron beam devices, and plasma dynamics. Acknowledgements The instructor would like to thank Xuancheng Shao and Anyang Hou for transcribing into LaTeX the problem set solution

Subjects

continuum mechanics | continuum mechanics | electromechanics | electromechanics | mechanical and electromechanical transfer relations | mechanical and electromechanical transfer relations | statics | statics | dynamics | dynamics | electromechanical systems | electromechanical systems | static equililbrium | static equililbrium | electromechanical flows | electromechanical flows | field coupling | field coupling | thermal and molecular diffusion | thermal and molecular diffusion | electrokinetics | electrokinetics | streaming interactions | streaming interactions | materials processing | materials processing | magnetohydrodynamic and electrohydrodynamic pumps and generators | magnetohydrodynamic and electrohydrodynamic pumps and generators | ferrohydrodynamics | ferrohydrodynamics | physiochemical systems | physiochemical systems | heat transfer | heat transfer | continuum feedback control | continuum feedback control | electron beam devices | electron beam devices | plasma dynamics | plasma dynamics

License

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5.111 Principles of Chemical Science (MIT) 5.111 Principles of Chemical Science (MIT)

Description

This course provides an introduction to the chemistry of biological, inorganic, and organic molecules. The emphasis is on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. In an effort to illuminate connections between chemistry and biology, a list of the biology-, medicine-, and MIT research-related examples used in 5.111 is provided in Biology-Related Examples. Acknowledgements Development and implementation of the biology-related materials in this course were funded through an HHMI Professors grant to Prof. Catherine L. Drennan. This course provides an introduction to the chemistry of biological, inorganic, and organic molecules. The emphasis is on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. In an effort to illuminate connections between chemistry and biology, a list of the biology-, medicine-, and MIT research-related examples used in 5.111 is provided in Biology-Related Examples. Acknowledgements Development and implementation of the biology-related materials in this course were funded through an HHMI Professors grant to Prof. Catherine L. Drennan.

Subjects

introductory chemistry | introductory chemistry | atomic structure | atomic structure | molecular electronic structure | molecular electronic structure | thermodynamics | thermodynamics | acid-base equillibrium | acid-base equillibrium | titration | titration | redox | redox | chemical kinetics | chemical kinetics | catalysis | catalysis | lewis structures | lewis structures | VSEPR theory | VSEPR theory | wave-particle duality | wave-particle duality | biochemistry | biochemistry | orbitals | orbitals | periodic trends | periodic trends | general chemistry | general chemistry | valence bond theory | valence bond theory | hybridization | hybridization | free energy | free energy | reaction mechanism | reaction mechanism | Rutherford backscattering | Rutherford backscattering

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Kinetics (MIT) Kinetics (MIT)

Description

This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions. This subject deals primarily with equilibrium properties of macroscopic systems, basic thermodynamics, chemical equilibrium of reactions in gas and solution phase, and rates of chemical reactions.

Subjects

thermodynamics | thermodynamics | kinetics | kinetics | equilibrium | equilibrium | macroscopic systems | macroscopic systems | state variables | state variables | law of thermodynamics | law of thermodynamics | entropy | entropy | Gibbs function | Gibbs function | reaction rates | reaction rates | clapeyron | clapeyron | enthalpy | enthalpy | clausius | clausius | adiabatic | adiabatic | Hemholtz | Hemholtz | catalysis | catalysis | oscillators | oscillators | autocatalysis | autocatalysis | carnot cycle | carnot cycle

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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