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2.60 Fundamentals of Advanced Energy Conversion (MIT) 2.60 Fundamentals of Advanced Energy Conversion (MIT)

Description

This course covers fundamentals of thermodynamics, chemistry, flow and transport processes as applied to energy systems. Topics include analysis of energy conversion in thermomechanical, thermochemical, electrochemical, and photoelectric processes in existing and future power and transportation systems, with emphasis on efficiency, environmental impact and performance. Systems utilizing fossil fuels, hydrogen, nuclear and renewable resources, over a range of sizes and scales are discussed. Applications include fuel reforming, hydrogen and synthetic fuel production, fuel cells and batteries, combustion, hybrids, catalysis, supercritical and combined cycles, photovoltaics, etc. The course also deals with different forms of energy storage and transmission, and optimal source utilization This course covers fundamentals of thermodynamics, chemistry, flow and transport processes as applied to energy systems. Topics include analysis of energy conversion in thermomechanical, thermochemical, electrochemical, and photoelectric processes in existing and future power and transportation systems, with emphasis on efficiency, environmental impact and performance. Systems utilizing fossil fuels, hydrogen, nuclear and renewable resources, over a range of sizes and scales are discussed. Applications include fuel reforming, hydrogen and synthetic fuel production, fuel cells and batteries, combustion, hybrids, catalysis, supercritical and combined cycles, photovoltaics, etc. The course also deals with different forms of energy storage and transmission, and optimal source utilization

Subjects

Thermodynamics | Thermodynamics | chemistry | chemistry | flow | flow | transport processes | transport processes | energy systems | energy systems | energy conversion in thermomechanical | thermochemical | electrochemical | energy conversion in thermomechanical | thermochemical | electrochemical | and photoelectric processes | and photoelectric processes | power and transportation systems | power and transportation systems | efficiency | efficiency | environmental impact | environmental impact | performance | performance | fossil fuels | fossil fuels | hydrogen resources | hydrogen resources | nuclear resources | nuclear resources | renewable resources | renewable resources | fuel reforming | fuel reforming | hydrogen and synthetic fuel production | hydrogen and synthetic fuel production | fuel cells and batteries | fuel cells and batteries | combustion | combustion | hybrids | hybrids | catalysis | catalysis | supercritical and combined cycles | supercritical and combined cycles | photovoltaics | photovoltaics | energy storage and transmission | energy storage and transmission | Optimal source utilization | Optimal source utilization | fuel-life cycle analysis. | fuel-life cycle analysis. | thermochemical | electrochemical | and photoelectric processes | thermochemical | electrochemical | and photoelectric processes | 2.62 | 2.62 | 10.392 | 10.392 | 22.40 | 22.40

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12.740 Paleoceanography (MIT) 12.740 Paleoceanography (MIT)

Description

This class examines tools, data, and ideas related to past climate changes as seen in marine, ice core, and continental records. The most recent climate changes (mainly the past 500,000 years, ranging up to about 2 million years ago) will be emphasized. Quantitative tools for the examination of paleoceanographic data will be introduced (statistics, factor analysis, time series analysis, simple climatology).Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files. This class examines tools, data, and ideas related to past climate changes as seen in marine, ice core, and continental records. The most recent climate changes (mainly the past 500,000 years, ranging up to about 2 million years ago) will be emphasized. Quantitative tools for the examination of paleoceanographic data will be introduced (statistics, factor analysis, time series analysis, simple climatology).Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files found on this course site. Free Microsoft® Excel viewer software can also be used to view the .xls files.

Subjects

history of the earth-surface environment | history of the earth-surface environment | deep-sea sediments | deep-sea sediments | ice cores | ice cores | corals | corals | Micropaleontological | Micropaleontological | isotopic | isotopic | geochemical | geochemical | and mineralogical changes | and mineralogical changes | seawater composition | seawater composition | atmospheric chemistry | atmospheric chemistry | climate | climate | ocean temperature | ocean temperature | circulation | circulation | chemistry | chemistry | glacial/interglacial cycles | glacial/interglacial cycles | orbital forcing | orbital forcing | geochemical | and mineralogical changes | geochemical | and mineralogical changes | 5. Micropaleontological | isotopic | geochemical | and mineralogical changes | 5. Micropaleontological | isotopic | geochemical | and mineralogical changes | Micropaleontological | isotopic | geochemical | and mineralogical changes | Micropaleontological | isotopic | geochemical | and mineralogical changes

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7.343 Photosynthesis: Life from Light (MIT) 7.343 Photosynthesis: Life from Light (MIT)

Description

In this course, you will journey through the web of physical, chemical, and biological reactions that collectively constitute photosynthesis. We will begin with light harvesting and follow photons to the sites of primary photochemistry: the photoreaction centers. A molecular-scale view will show in atomic detail how these protein complexes capture and energize electrons. Then we will follow the multiple pathways electrons take as they carry out their work. Consequent reactions, such as the synthesis of ATP and the reduction of CO2 during the synthesis of carbohydrates, will also be discussed in structural detail. Lastly, we will delve into the evolution of these systems and also discuss other photosynthetic strategies, such as light-driven proton pumps and anoxygenic photosynthesis. The co In this course, you will journey through the web of physical, chemical, and biological reactions that collectively constitute photosynthesis. We will begin with light harvesting and follow photons to the sites of primary photochemistry: the photoreaction centers. A molecular-scale view will show in atomic detail how these protein complexes capture and energize electrons. Then we will follow the multiple pathways electrons take as they carry out their work. Consequent reactions, such as the synthesis of ATP and the reduction of CO2 during the synthesis of carbohydrates, will also be discussed in structural detail. Lastly, we will delve into the evolution of these systems and also discuss other photosynthetic strategies, such as light-driven proton pumps and anoxygenic photosynthesis. The co

Subjects

photosynthesis | photosynthesis | life from light | life from light | conversion | conversion | solar energy | solar energy | chemical energy | chemical energy | biogeochemical cycles | biogeochemical cycles | global warming | global warming | physical | physical | chemical and biological reactions | chemical and biological reactions | light harvesting | light harvesting | photochemistry | photochemistry | protein complexes | protein complexes | synthesis of ATP | synthesis of ATP | reduction of CO2 | reduction of CO2 | carbohydrates | carbohydrates | light-driven proton pumps | light-driven proton pumps | anoxygenic photosynthesis | anoxygenic photosynthesis

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5.05 Principles of Inorganic Chemistry III (MIT) 5.05 Principles of Inorganic Chemistry III (MIT)

Description

This course covers the principles of main group (s and p block) element chemistry with an emphasis on synthesis, structure, bonding, and reaction mechanisms. This course covers the principles of main group (s and p block) element chemistry with an emphasis on synthesis, structure, bonding, and reaction mechanisms.

Subjects

inorganic chemistry | inorganic chemistry | main group element chemistry | main group element chemistry | chemical synthesis | chemical synthesis | chemical structure | chemical structure | bonding | bonding | reaction mechanisms | reaction mechanisms | aluminum chemistry | aluminum chemistry | s block | s block | p block | p block | interatomic distance | interatomic distance | lewis structure | lewis structure | partitions space | partitions space | Density Functional Theory | Density Functional Theory | NMR spectroscopy | NMR spectroscopy | spin-orbit coupling | spin-orbit coupling | spin-spin coupling | spin-spin coupling | relativistic effects | relativistic effects | spin-orbit effects | spin-orbit effects | noble gas chemistry | noble gas chemistry | chemical reaction products | chemical reaction products

License

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3.20 Materials at Equilibrium (SMA 5111) (MIT) 3.20 Materials at Equilibrium (SMA 5111) (MIT)

Description

Material covered in this course includes the following topics: Laws of thermodynamics: general formulation and applications to mechanical, electromagnetic and electrochemical systems, solutions, and phase diagrams Computation of phase diagrams Statistical thermodynamics and relation between microscopic and macroscopic properties, including ensembles, gases, crystal lattices, phase transitions Applications to phase stability and properties of mixtures Computational modeling Interfaces This course was also taught as part of the Singapore-MIT Alliance (SMA) programme as course number SMA 5111 (Materials at Equilibrium). Material covered in this course includes the following topics: Laws of thermodynamics: general formulation and applications to mechanical, electromagnetic and electrochemical systems, solutions, and phase diagrams Computation of phase diagrams Statistical thermodynamics and relation between microscopic and macroscopic properties, including ensembles, gases, crystal lattices, phase transitions Applications to phase stability and properties of mixtures Computational modeling Interfaces This course was also taught as part of the Singapore-MIT Alliance (SMA) programme as course number SMA 5111 (Materials at Equilibrium).

Subjects

thermodynamics | thermodynamics | mechanical | mechanical | electromagnetic and electrochemical systems | electromagnetic and electrochemical systems | phase diagrams | phase diagrams | Statistical thermodynamics | Statistical thermodynamics | microscopic and macroscopic properties | microscopic and macroscopic properties | ensembles | ensembles | gases | gases | crystal lattices | crystal lattices | phase transitions | phase transitions | phase stability | phase stability | properties of mixtures | properties of mixtures | Computational modeling | Computational modeling | Interfaces | Interfaces | mechanical | electromagnetic and electrochemical systems | mechanical | electromagnetic and electrochemical systems | Computational modeling; Interfaces | Computational modeling; Interfaces | mechanical systems | mechanical systems | electromagnetic systems | electromagnetic systems | electrochemical systems | electrochemical systems | laws of thermodynamics | laws of thermodynamics | solutions | solutions | microscopic properties | microscopic properties | macroscopic properties | macroscopic properties

License

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6.152J Microelectronics Processing Technology (MIT) 6.152J Microelectronics Processing Technology (MIT)

Description

This course introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions focus on basic processing techniques such as diffusion, oxidation, photolithography, chemical vapor deposition, and more. Through team lab assignments, students are expected to gain an understanding of these processing techniques, and how they are applied in concert to device fabrication. Students enrolled in this course have a unique opportunity to fashion and test micro/nano-devices, using modern techniques and technology. This course introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions focus on basic processing techniques such as diffusion, oxidation, photolithography, chemical vapor deposition, and more. Through team lab assignments, students are expected to gain an understanding of these processing techniques, and how they are applied in concert to device fabrication. Students enrolled in this course have a unique opportunity to fashion and test micro/nano-devices, using modern techniques and technology.

Subjects

microelectronics | microelectronics | Microelectronics processing | Microelectronics processing | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | integrated circuits | vacuum | chemical vapor deposition | CVD | oxidation | diffusion | implantation | lithography | soft lithography | etching | sputtering | evaporation | interconnect | metallization | crystal growth | reliability | fabrication | processing | photolithography | physical vapor deposition | MOS | MOS capacitor | microcantilever | microfluidic | integrated circuits;vacuum;chemical vapor deposition;CVD;oxidation;diffusion;implantation;lithography;soft lithography;etching;sputtering;evaporation;interconnect;metallization;crystal growth;reliability;fabrication;processing;photolithography;physical vapor deposition;MOS;MOS capacitor;microcantilever;microfluidic | integrated circuits;vacuum;chemical vapor deposition;CVD;oxidation;diffusion;implantation;lithography;soft lithography;etching;sputtering;evaporation;interconnect;metallization;crystal growth;reliability;fabrication;processing;photolithography;physical vapor deposition;MOS;MOS capacitor;microcantilever;microfluidic | integrated circuits | integrated circuits | vacuum | vacuum | chemical vapor deposition | chemical vapor deposition | CVD | CVD | oxidation | oxidation | diffusion | diffusion | implantation | implantation | lithography | lithography | soft lithography | soft lithography | etching | etching | sputtering | sputtering | evaporation | evaporation | interconnect | interconnect | metallization | metallization | crystal growth | crystal growth | reliability | reliability | fabrication | fabrication | processing | processing | photolithography | photolithography | physical vapor deposition | physical vapor deposition | MOS | MOS | MOS capacitor | MOS capacitor | microcantilever | microcantilever | microfluidic | microfluidic | 6.152 | 6.152 | 3.155 | 3.155

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10.520 Molecular Aspects of Chemical Engineering (MIT) 10.520 Molecular Aspects of Chemical Engineering (MIT)

Description

This class covers molecular-level engineering and analysis of chemical processes. The use of chemical bonding, reactivity, and other key concepts in the design and tailoring of organic systems are discussed in this class. Specific class topics include application and development of structure-property relationships, and descriptions of the chemical forces and structural factors that govern supramolecular and interfacial phenomena for molecular and polymeric systems. This class covers molecular-level engineering and analysis of chemical processes. The use of chemical bonding, reactivity, and other key concepts in the design and tailoring of organic systems are discussed in this class. Specific class topics include application and development of structure-property relationships, and descriptions of the chemical forces and structural factors that govern supramolecular and interfacial phenomena for molecular and polymeric systems.

Subjects

molecular-level engineering | molecular-level engineering | analysis of chemical processes | analysis of chemical processes | chemical bonding | chemical bonding | reactivity | reactivity | design of organic systems | design of organic systems | tailoring of organic systems | tailoring of organic systems | application and development of structure-property relationships | application and development of structure-property relationships | descriptions of the chemical forces and structural factors that govern supramolecular and interfacial phenomena for molecular and polymeric systems | descriptions of the chemical forces and structural factors that govern supramolecular and interfacial phenomena for molecular and polymeric systems

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2.625 Electrochemical Energy Conversion and Storage: Fundamentals, Materials, and Applications (MIT) 2.625 Electrochemical Energy Conversion and Storage: Fundamentals, Materials, and Applications (MIT)

Description

This course will introduce students to the principles, performance, and challenges of electrochemical and photoelectrochemical devices. This will be done in the context of global energy needs and challenges, and will include an overview of different energy technologies. This course will introduce students to the principles, performance, and challenges of electrochemical and photoelectrochemical devices. This will be done in the context of global energy needs and challenges, and will include an overview of different energy technologies.

Subjects

electrochemistry | electrochemistry | battery | battery | fuel cell | fuel cell | energy | energy | electrodes | electrodes | solid oxide fuel cell | solid oxide fuel cell | lithium ion battery | lithium ion battery | proton exchange membrane | proton exchange membrane | electrical double layer | electrical double layer | chemical equilibrium | chemical equilibrium | chemical potential | chemical potential | catalysis | catalysis | Butler-Volmer model | Butler-Volmer model | electrochemical impedance spectroscopy | electrochemical impedance spectroscopy | kinetics | kinetics | surface reactivity | surface reactivity

License

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5.33 Advanced Chemical Experimentation and Instrumentation (MIT) 5.33 Advanced Chemical Experimentation and Instrumentation (MIT)

Description

5.33 focuses on advanced experimentation, with particular emphasis on chemical synthesis and the fundamentals of quantum chemistry, illustrated through molecular spectroscopy. The written and oral presentation of experimental results is also emphasized in the course.WARNING NOTICE:The experiments described in these materials are potentially hazardous andrequire a high level of safety training, special facilities and equipment, and supervision by appropriateindividuals. You bear the sole responsibility, liability, and risk for the implementation of such safetyprocedures and measures. MIT shall have no responsibility, liability, or risk for the content or implementationof any of the material presented.Legal Notice<br clear="all&gt;&lt;br clear=" all="all" /> 5.33 focuses on advanced experimentation, with particular emphasis on chemical synthesis and the fundamentals of quantum chemistry, illustrated through molecular spectroscopy. The written and oral presentation of experimental results is also emphasized in the course.WARNING NOTICE:The experiments described in these materials are potentially hazardous andrequire a high level of safety training, special facilities and equipment, and supervision by appropriateindividuals. You bear the sole responsibility, liability, and risk for the implementation of such safetyprocedures and measures. MIT shall have no responsibility, liability, or risk for the content or implementationof any of the material presented.Legal Notice<br clear="all&gt;&lt;br clear=" all="all" />

Subjects

advanced chemical experimentation | advanced chemical experimentation | Instrumentation | Instrumentation | experiment | experiment | chemistry | chemistry | laboratory | laboratory | integrated chemisty laboratory | integrated chemisty laboratory | chemical synthesis | chemical synthesis | quantum chemistry | quantum chemistry | molecular spectroscopy | molecular spectroscopy

License

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[Aerial View, Texas City Plant, Monsanto Chemical Co.]

Description

Subjects

aerialviews | aerials | gulfcoast | industrialfacilities | storagetanks | chemicalplants | chemicalindustries | agriculturalchemicals | agriculturalbiotechnology | monsantochemicalcompany

License

No known copyright restrictions

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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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5.46 Organic Structure Determination (MIT) 5.46 Organic Structure Determination (MIT)

Description

This course covers modern and advanced methods of elucidation of the structures of organic molecules, including NMR, MS, and IR (among others). The fundamental physical and chemical principles of each method will be discussed.&#160;The major emphasis of this course is on structure determination by way of interpreting the data (generally in the form of a spectrum or spectra) that each method provides. This course covers modern and advanced methods of elucidation of the structures of organic molecules, including NMR, MS, and IR (among others). The fundamental physical and chemical principles of each method will be discussed.&#160;The major emphasis of this course is on structure determination by way of interpreting the data (generally in the form of a spectrum or spectra) that each method provides.

Subjects

organic structure determination | organic structure determination | relative configuration | relative configuration | elemental analysis | elemental analysis | mass spectometry | mass spectometry | index of hydrogen deficiency | index of hydrogen deficiency | EA | EA | MS | MS | IHD | IHD | infrared spectroscopy | infrared spectroscopy | IR | IR | nuclear magnetic resonance spectroscopy | nuclear magnetic resonance spectroscopy | NMR | NMR | chemical equivalence | chemical equivalence | non-equivalence | non-equivalence | topicity | topicity | spin-spin splitting | spin-spin splitting | J coupling | J coupling | chemical shift | chemical shift

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2.60 Fundamentals of Advanced Energy Conversion (MIT)

Description

This course covers fundamentals of thermodynamics, chemistry, flow and transport processes as applied to energy systems. Topics include analysis of energy conversion in thermomechanical, thermochemical, electrochemical, and photoelectric processes in existing and future power and transportation systems, with emphasis on efficiency, environmental impact and performance. Systems utilizing fossil fuels, hydrogen, nuclear and renewable resources, over a range of sizes and scales are discussed. Applications include fuel reforming, hydrogen and synthetic fuel production, fuel cells and batteries, combustion, hybrids, catalysis, supercritical and combined cycles, photovoltaics, etc. The course also deals with different forms of energy storage and transmission, and optimal source utilization

Subjects

Thermodynamics | chemistry | flow | transport processes | energy systems | energy conversion in thermomechanical | thermochemical | electrochemical | and photoelectric processes | power and transportation systems | efficiency | environmental impact | performance | fossil fuels | hydrogen resources | nuclear resources | renewable resources | fuel reforming | hydrogen and synthetic fuel production | fuel cells and batteries | combustion | hybrids | catalysis | supercritical and combined cycles | photovoltaics | energy storage and transmission | Optimal source utilization | fuel-life cycle analysis. | thermochemical | electrochemical | and photoelectric processes | 2.62 | 10.392 | 22.40

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12.740 Paleoceanography (MIT)

Description

This class examines tools, data, and ideas related to past climate changes as seen in marine, ice core, and continental records. The most recent climate changes (mainly the past 500,000 years, ranging up to about 2 million years ago) will be emphasized. Quantitative tools for the examination of paleoceanographic data will be introduced (statistics, factor analysis, time series analysis, simple climatology).Technical RequirementsMicrosoft&reg; Excel software&nbsp;is recommended for viewing the .xls files found on this course site. Free&nbsp;Microsoft&reg; Excel viewer software&nbsp;can also be used to view the .xls files.

Subjects

history of the earth-surface environment | deep-sea sediments | ice cores | corals | Micropaleontological | isotopic | geochemical | and mineralogical changes | seawater composition | atmospheric chemistry | climate | ocean temperature | circulation | chemistry | glacial/interglacial cycles | orbital forcing | geochemical | and mineralogical changes | 5. Micropaleontological | isotopic | geochemical | and mineralogical changes | Micropaleontological | isotopic | geochemical | and mineralogical changes

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12.742 Marine Chemistry (MIT) 12.742 Marine Chemistry (MIT)

Description

Includes audio/video content: AV selected lectures. This course is an introduction to chemical oceanography. It describes reservoir models and residence time, major ion composition of seawater, inputs to and outputs from the ocean via rivers, the atmosphere, and the sea floor. Biogeochemical cycling within the oceanic water column and sediments, emphasizing the roles played by the formation, transport, and alteration of oceanic particles and the effects that these processes have on seawater composition. Cycles of carbon, nitrogen, phosphorus, oxygen, and sulfur. Uptake of anthropogenic carbon dioxide by the ocean. Material presented through lectures and student-led presentation and discussion of recent papers. Includes audio/video content: AV selected lectures. This course is an introduction to chemical oceanography. It describes reservoir models and residence time, major ion composition of seawater, inputs to and outputs from the ocean via rivers, the atmosphere, and the sea floor. Biogeochemical cycling within the oceanic water column and sediments, emphasizing the roles played by the formation, transport, and alteration of oceanic particles and the effects that these processes have on seawater composition. Cycles of carbon, nitrogen, phosphorus, oxygen, and sulfur. Uptake of anthropogenic carbon dioxide by the ocean. Material presented through lectures and student-led presentation and discussion of recent papers.

Subjects

chemical oceanography | chemical oceanography | biogeochemical cycling | biogeochemical cycling | water column processes | water column processes | ocean particles | ocean particles | seawater composition | seawater composition | ocean particle transport | ocean particle transport | carbon | carbon | oxygen | oxygen | nitrogen | nitrogen | phosphorus | phosphorus | sulfur | sulfur | carbon dioxide | carbon dioxide | sediment chemistry | sediment chemistry

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10.626 Electrochemical Energy Systems (MIT) 10.626 Electrochemical Energy Systems (MIT)

Description

This course introduces principles and mathematical models of electrochemical energy conversion and storage. Students study equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. In addition, this course includes applications to batteries, fuel cells, supercapacitors, and electrokinetics. This course introduces principles and mathematical models of electrochemical energy conversion and storage. Students study equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. In addition, this course includes applications to batteries, fuel cells, supercapacitors, and electrokinetics.

Subjects

energy | energy | electrochemical energy conversion | electrochemical energy conversion | electrochemical energy storage | electrochemical energy storage | transport phenomena | transport phenomena | diffuse charge | diffuse charge | Faradaic reactions | Faradaic reactions | statistical thermodynamics | statistical thermodynamics | phase transformations | phase transformations | rechargeable batteries | rechargeable batteries | fuel cells | fuel cells | supercapacitors | supercapacitors | solar cells | solar cells | desalination | desalination | electrokinetic energy conversion | electrokinetic energy conversion

License

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7.016 Introductory Biology (MIT) 7.016 Introductory Biology (MIT)

Description

7.016 Introductory Biology provides an introduction to fundamental principles of biochemistry, molecular biology and genetics for understanding the functions of living systems. Taught for the first time in Fall 2013, this course covers examples of the use of chemical biology and twenty-first-century molecular genetics in understanding human health and therapeutic intervention. The MIT Biology Department Introductory Biology courses, 7.012, 7.013, 7.014, 7.015, and 7.016 all cover the same core material, which includes the fundamental principles of biochemistry, genetics, molecular biology, and cell biology. Biological function at the molecular level is particularly emphasized and covers the structure and regulation of genes, as well as the structure and synthesis of proteins, how these mol 7.016 Introductory Biology provides an introduction to fundamental principles of biochemistry, molecular biology and genetics for understanding the functions of living systems. Taught for the first time in Fall 2013, this course covers examples of the use of chemical biology and twenty-first-century molecular genetics in understanding human health and therapeutic intervention. The MIT Biology Department Introductory Biology courses, 7.012, 7.013, 7.014, 7.015, and 7.016 all cover the same core material, which includes the fundamental principles of biochemistry, genetics, molecular biology, and cell biology. Biological function at the molecular level is particularly emphasized and covers the structure and regulation of genes, as well as the structure and synthesis of proteins, how these mol

Subjects

biochemistry | biochemistry | molecular biology | molecular biology | genetics | genetics | human genetics | human genetics | pedigrees | pedigrees | biochemical genetics | biochemical genetics | chemical biology | chemical biology | molecular genetics | molecular genetics | recombinant DNA technology | recombinant DNA technology | cell biology | cell biology | cancer | cancer | viruses | viruses | HIV | HIV | bacteria | bacteria | antibiotics | antibiotics | human health | human health | therapeutic intervention | therapeutic intervention | cell signaling | cell signaling | evolution | evolution | reproduction | reproduction | infectious diseases | infectious diseases | therapeutics | therapeutics

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

Description

This course covers elementary statistical mechanics, transport properties, kinetic theory, solid state, reaction rate theory, and chemical reaction dynamics. Acknowledgements 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 course covers elementary statistical mechanics, transport properties, kinetic theory, solid state, reaction rate theory, and chemical reaction dynamics. Acknowledgements 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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2.60 Fundamentals of Advanced Energy Conversion (MIT)

Description

This course covers fundamentals of thermodynamics, chemistry, flow and transport processes as applied to energy systems. Topics include analysis of energy conversion in thermomechanical, thermochemical, electrochemical, and photoelectric processes in existing and future power and transportation systems, with emphasis on efficiency, environmental impact and performance. Systems utilizing fossil fuels, hydrogen, nuclear and renewable resources, over a range of sizes and scales are discussed. Applications include fuel reforming, hydrogen and synthetic fuel production, fuel cells and batteries, combustion, hybrids, catalysis, supercritical and combined cycles, photovoltaics, etc. The course also deals with different forms of energy storage and transmission, and optimal source utilization

Subjects

Thermodynamics | chemistry | flow | transport processes | energy systems | energy conversion in thermomechanical | thermochemical | electrochemical | and photoelectric processes | power and transportation systems | efficiency | environmental impact | performance | fossil fuels | hydrogen resources | nuclear resources | renewable resources | fuel reforming | hydrogen and synthetic fuel production | fuel cells and batteries | combustion | hybrids | catalysis | supercritical and combined cycles | photovoltaics | energy storage and transmission | Optimal source utilization | fuel-life cycle analysis. | thermochemical | electrochemical | and photoelectric processes | 2.62 | 10.392 | 22.40

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5.46 Organic Structure Determination (MIT) 5.46 Organic Structure Determination (MIT)

Description

This course covers modern and advanced methods of elucidation of the structures of organic molecules, including NMR, MS, and IR (among others). The fundamental physical and chemical principles of each method will be discussed. The major emphasis of this course is on structure determination by way of interpreting the data (generally in the form of a spectrum or spectra) that each method provides. This course covers modern and advanced methods of elucidation of the structures of organic molecules, including NMR, MS, and IR (among others). The fundamental physical and chemical principles of each method will be discussed. The major emphasis of this course is on structure determination by way of interpreting the data (generally in the form of a spectrum or spectra) that each method provides.

Subjects

organic structure determination | organic structure determination | relative configuration | relative configuration | elemental analysis | elemental analysis | mass spectometry | mass spectometry | index of hydrogen deficiency | index of hydrogen deficiency | EA | EA | MS | MS | IHD | IHD | infrared spectroscopy | infrared spectroscopy | IR | IR | nuclear magnetic resonance spectroscopy | nuclear magnetic resonance spectroscopy | NMR | NMR | chemical equivalence | chemical equivalence | non-equivalence | non-equivalence | topicity | topicity | spin-spin splitting | spin-spin splitting | J coupling | J coupling | chemical shift | chemical shift

License

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5.302 Introduction to Experimental Chemistry (MIT) 5.302 Introduction to Experimental Chemistry (MIT)

Description

5.302 is a 3-unit course intended to provide freshmen with a stimulating and enjoyable "hands-on" experience with chemical phenomena. The aim of this course is to provide freshmen with an opportunity to get "up close and personal" with the chemical phenomena introduced in 5.111, 5.112 and 3.091. Interesting and dramatic experiments have been selected to illustrate and reinforce the concepts and principles introduced in the chemistry core lecture courses.   WARNING NOTICE The experiments described in these materials are potentially hazardous and require a high level of safety training, special facilities and equipment, and supervision by appropriate individuals. You bear the sole responsibility, liability, and risk for the implementation of such safety procedur 5.302 is a 3-unit course intended to provide freshmen with a stimulating and enjoyable "hands-on" experience with chemical phenomena. The aim of this course is to provide freshmen with an opportunity to get "up close and personal" with the chemical phenomena introduced in 5.111, 5.112 and 3.091. Interesting and dramatic experiments have been selected to illustrate and reinforce the concepts and principles introduced in the chemistry core lecture courses.   WARNING NOTICE The experiments described in these materials are potentially hazardous and require a high level of safety training, special facilities and equipment, and supervision by appropriate individuals. You bear the sole responsibility, liability, and risk for the implementation of such safety procedur

Subjects

experimental chemistry | experimental chemistry | chemistry experiments | chemistry experiments | chemical equilibrium | chemical equilibrium | coordination chemistry | coordination chemistry | solubility equilibrium | solubility equilibrium | redox chemistry | redox chemistry | Tollen's test | Tollen's test | chemical kinetics | chemical kinetics | iodine clock | iodine clock | nylon 6-10 | nylon 6-10 | methyl orange | methyl orange

License

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5.08J Biological Chemistry II (MIT) 5.08J Biological Chemistry II (MIT)

Description

This course deals with a more advanced treatment of the biochemical mechanisms that underlie biological processes. Emphasis will be given to the experimental methods used to unravel how these processes fit into the cellular context as well as the coordinated regulation of these processes. Topics include macromolecular machines for energy and force transduction, regulation of biosynthetic and degradative pathways, and the structure and function of nucleic acids. This course deals with a more advanced treatment of the biochemical mechanisms that underlie biological processes. Emphasis will be given to the experimental methods used to unravel how these processes fit into the cellular context as well as the coordinated regulation of these processes. Topics include macromolecular machines for energy and force transduction, regulation of biosynthetic and degradative pathways, and the structure and function of nucleic acids.

Subjects

biochemistry | biochemistry | biological chemistry | biological chemistry | Rasmol | Rasmol | Deep Viewer | Deep Viewer | CHIME | CHIME | BLAST | BLAST | PDB | PDB | macromolecular machines | macromolecular machines | protein folding | protein folding | protein degradation | protein degradation | fatty acid synthases | fatty acid synthases | polyketide synthases | polyketide synthases | non-ribosomal polypeptide synthases | non-ribosomal polypeptide synthases | metal homeostasis | metal homeostasis | biochemical mechanisms | biochemical mechanisms | biochemical pathways | biochemical pathways | macromolecular interactions | macromolecular interactions | ribosome | ribosome | mRNA | mRNA | metabolic networking | metabolic networking | 5.08 | 5.08 | 7.08 | 7.08

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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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5.32 Intermediate Chemical Experimentation (MIT) 5.32 Intermediate Chemical Experimentation (MIT)

Description

5.32 involves more advanced experimental work than 5.310 or 5.311. The course emphasizes organic synthesis assisted by chiral catalysis, purification, and analysis of organic compounds employing such methods as IR, 1D and 2D NMR, UV spectroscopies and mass spectrometry, and thin layer and non-chiral and chiral gas chromatography. In 5.32, experiments also involve enzyme purification, characterization and assays, as well as molecular modeling in organic synthesis and in biochemical systems. WARNING NOTICE The experiments described in these materials are potentially hazardous and require a high level of safety training, special facilities and equipment, and supervision by appropriate individuals. You bear the sole responsibility, liability, and risk for the implementation of such 5.32 involves more advanced experimental work than 5.310 or 5.311. The course emphasizes organic synthesis assisted by chiral catalysis, purification, and analysis of organic compounds employing such methods as IR, 1D and 2D NMR, UV spectroscopies and mass spectrometry, and thin layer and non-chiral and chiral gas chromatography. In 5.32, experiments also involve enzyme purification, characterization and assays, as well as molecular modeling in organic synthesis and in biochemical systems. WARNING NOTICE The experiments described in these materials are potentially hazardous and require a high level of safety training, special facilities and equipment, and supervision by appropriate individuals. You bear the sole responsibility, liability, and risk for the implementation of such

Subjects

intermediate chemical experimentation | intermediate chemical experimentation | experiment | experiment | chemistry | chemistry | organic synthesis | organic synthesis | chiral catalysis | chiral catalysis | purification | purification | organic chemistry | organic chemistry | laboratory | laboratory | IR | IR | 1D NMR | 1D NMR | 2D NMR | 2D NMR | UV spectroscopy | UV spectroscopy | mass spectrometry | mass spectrometry | thin layer gas chromatography | thin layer gas chromatography | non-chiral gas chromatography | non-chiral gas chromatography | chiral gas chromatography | chiral gas chromatography | enzyme purification | enzyme purification | characterization | characterization | assays | assays | molecular modeling | molecular modeling | biochemical systems | biochemical systems

License

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11.479J Water and Sanitation Infrastructure in Developing Countries (MIT) 11.479J Water and Sanitation Infrastructure in Developing Countries (MIT)

Description

This course deals with the principles of infrastructure planning in developing countries, with a focus on appropriate and sustainable technologies for water and sanitation. It also incorporates technical, socio-cultural, public health, and economic factors into the planning and design of water and sanitation systems. Upon completion, students will be able to plan simple, yet reliable, water supply and sanitation systems for developing countries that are compatible with local customs and available human and material resources. Graduate and upper division students from any department who are interested in international development at the grassroots level are encouraged to participate in this interdisciplinary subject. Acknowledgment This course was jointly developed by Earthea Nance and Sus This course deals with the principles of infrastructure planning in developing countries, with a focus on appropriate and sustainable technologies for water and sanitation. It also incorporates technical, socio-cultural, public health, and economic factors into the planning and design of water and sanitation systems. Upon completion, students will be able to plan simple, yet reliable, water supply and sanitation systems for developing countries that are compatible with local customs and available human and material resources. Graduate and upper division students from any department who are interested in international development at the grassroots level are encouraged to participate in this interdisciplinary subject. Acknowledgment This course was jointly developed by Earthea Nance and Sus

Subjects

chemical oceanography | chemical oceanography | biogeochemical cycling | biogeochemical cycling | water column processes | water column processes | ocean particles | ocean particles | seawater composition | seawater composition | ocean particle transport | ocean particle transport | carbon | carbon | oxygen | oxygen | nitrogen | nitrogen | phosphorus | phosphorus | sulfur | sulfur | carbon dioxide | carbon dioxide | sediment chemistry | sediment chemistry

License

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