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Chemical and Environmental Behaviour of Materials: Fuel Cells
Description
This set of animations demonstrates the principles of a solid oxide fuel cell and a proton exchange membrane cell. From TLP: Fuel CellsSubjects
fuel cells | SOFC | PEMFC | Solid oxide fuel cell | Proton exchange membrane fuel cell | polymer electrolyte membrane fuel cell | DoITPoMS | University of Cambridge | animation | corematerials | ukoerLicense
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See all metadataChemical and Environmental Behaviour of Materials: Fuel Cells
Description
This set of animations demonstrates the principles of a solid oxide fuel cell and a proton exchange membrane cell. From TLP: Fuel CellsSubjects
fuel cells | sofc | pemfc | solid oxide fuel cell | proton exchange membrane fuel cell | polymer electrolyte membrane fuel cell | doitpoms | university of cambridge | animation | corematerials | ukoer | Engineering | H000License
Attribution-Noncommercial-Share Alike 2.0 UK: England & Wales Attribution-Noncommercial-Share Alike 2.0 UK: England & Wales http://creativecommons.org/licenses/by-nc-sa/2.0/uk/ http://creativecommons.org/licenses/by-nc-sa/2.0/uk/Site sourced from
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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 reactivityLicense
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.htmSite sourced from
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This course provides an in-depth technical and policy analysis of various options for the nuclear fuel cycle. Topics include uranium supply, enrichment fuel fabrication, in-core physics and fuel management of uranium, thorium and other fuel types, reprocessing and waste disposal. Also covered are the principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of actinides and selected fission products in spent fuel are examined. Several state-of-the-art computer programs are provided for student use in problem sets and term papers. This course provides an in-depth technical and policy analysis of various options for the nuclear fuel cycle. Topics include uranium supply, enrichment fuel fabrication, in-core physics and fuel management of uranium, thorium and other fuel types, reprocessing and waste disposal. Also covered are the principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of actinides and selected fission products in spent fuel are examined. Several state-of-the-art computer programs are provided for student use in problem sets and term papers.Subjects
nuclear fuel | nuclear fuel | nuclear fuel cycle | nuclear fuel cycle | thorium fuel | thorium fuel | dry recycling | dry recycling | transmutation | transmutation | radioactive waste disposal | radioactive waste disposal | waste storage | waste storage | nuclear waste | nuclear waste | nuclear reactor analysis | nuclear reactor analysis | fuel cell design | fuel cell design | reactor design | reactor design | fast reactors | fast reactors | breeder reactors | breeder reactors | CANDU reactor | CANDU reactor | light water reactor | light water reactor | LWR | LWR | nuclear non-proliferation | nuclear non-proliferation | plutonium recycling | plutonium recyclingLicense
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.htmSite sourced from
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See all metadata3.014 Materials Laboratory (MIT) 3.014 Materials Laboratory (MIT)
Description
This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degre This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degreSubjects
electron | electron | electronic properties | electronic properties | magnetism | magnetism | magentic properties | magentic properties | structure | structure | crystal | crystal | lattice | lattice | energy | energy | thermodynamics | thermodynamics | differential scanning calorimetry (DSC) | differential scanning calorimetry (DSC) | x-ray diffraction (XRD) | x-ray diffraction (XRD) | scanning probe microscopy (AFM | scanning probe microscopy (AFM | STM) | STM) | scanning electron microscopy (SEM) | scanning electron microscopy (SEM) | UV/Vis | UV/Vis | Raman spectroscopy | Raman spectroscopy | FTIR spectroscopy | FTIR spectroscopy | x-ray photoelectron spectroscopy (XPS) | x-ray photoelectron spectroscopy (XPS) | vibrating sample magnetometry (VSM) | vibrating sample magnetometry (VSM) | dynamic light scattering (DLS) | dynamic light scattering (DLS) | phonon | phonon | quantum | quantum | quantum mechanics | quantum mechanics | radiation | radiation | battery | battery | fuel cell | fuel cell | ferromagnetism | ferromagnetism | ferromagnetic | ferromagnetic | polymer | polymer | glass | glass | corrosion | corrosionLicense
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.htmSite sourced from
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See all metadata3.014 Materials Laboratory (MIT) 3.014 Materials Laboratory (MIT)
Description
This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degre This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degreSubjects
electron | electron | electronic properties | electronic properties | magnetism | magnetism | magentic properties | magentic properties | structure | structure | crystal | crystal | lattice | lattice | energy | energy | thermodynamics | thermodynamics | differential scanning calorimetry (DSC) | differential scanning calorimetry (DSC) | x-ray diffraction (XRD) | x-ray diffraction (XRD) | scanning probe microscopy (AFM | scanning probe microscopy (AFM | STM) | STM) | scanning electron microscopy (SEM) | scanning electron microscopy (SEM) | UV/Vis | UV/Vis | Raman spectroscopy | Raman spectroscopy | FTIR spectroscopy | FTIR spectroscopy | x-ray photoelectron spectroscopy (XPS) | x-ray photoelectron spectroscopy (XPS) | vibrating sample magnetometry (VSM) | vibrating sample magnetometry (VSM) | dynamic light scattering (DLS) | dynamic light scattering (DLS) | phonon | phonon | quantum | quantum | quantum mechanics | quantum mechanics | radiation | radiation | battery | battery | fuel cell | fuel cell | ferromagnetism | ferromagnetism | ferromagnetic | ferromagnetic | polymer | polymer | glass | glass | corrosion | corrosionLicense
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.htmSite sourced from
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This course covers a variety of topics concerning superconducting magnets, including thermodynamic and transport properties of aqueous and nonaqueous electrolytes, the electrode/electrolyte interface, and the kinetics of electrode processes. It also covers electrochemical characterization with regards to d.c. techniques (controlled potential, controlled current) and a.c. techniques (voltametry and impedance spectroscopy). Applications of the following will also be discussed: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells). This course covers a variety of topics concerning superconducting magnets, including thermodynamic and transport properties of aqueous and nonaqueous electrolytes, the electrode/electrolyte interface, and the kinetics of electrode processes. It also covers electrochemical characterization with regards to d.c. techniques (controlled potential, controlled current) and a.c. techniques (voltametry and impedance spectroscopy). Applications of the following will also be discussed: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells).Subjects
Thermodynamic and transport properties of aqueous and nonaqueous electrolytes | Thermodynamic and transport properties of aqueous and nonaqueous electrolytes | electrode/electrolyte interface | electrode/electrolyte interface | Kinetics of electrode processes | Kinetics of electrode processes | Electrochemical characterization | Electrochemical characterization | d.c. techniques (controlled potential | controlled current) | d.c. techniques (controlled potential | controlled current) | a.c. techniques (voltametry and impedance spectroscopy) | a.c. techniques (voltametry and impedance spectroscopy) | electrowinning | electrowinning | electrorefining | electrorefining | electroplating | electroplating | electrosynthesis | electrosynthesis | electrochemical power sources (batteries and fuel cells) | electrochemical power sources (batteries and fuel cells)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.htmSite sourced from
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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 utilizationSubjects
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 | 22.40License
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.htmSite sourced from
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See all metadata10.626 Electrochemical Energy Systems (MIT) 10.626 Electrochemical Energy Systems (MIT)
Description
10.626 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. 10.626 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 conversionLicense
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.htmSite sourced from
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See all metadata10.626 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 conversionLicense
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.htmSite sourced from
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See all metadata10.626 Electrochemical Energy Systems (MIT) 10.626 Electrochemical Energy Systems (MIT)
Description
10.626 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. 10.626 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 conversionLicense
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.htmSite sourced from
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See all metadata2.60 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 utilizationSubjects
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 | 22.40License
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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A-level revision resource: Fuel CellsSubjects
chemistry | fuel cells | green energy | hydrogen | catalysts | anode | cathode | half equations | oxidation | reduction | oil rig | SCIENCES and MATHEMATICS | RLicense
Attribution-Noncommercial-No Derivative Works 2.0 UK: England & Wales Attribution-Noncommercial-No Derivative Works 2.0 UK: England & Wales http://creativecommons.org/licenses/by-nc-nd/2.0/uk/ http://creativecommons.org/licenses/by-nc-nd/2.0/uk/Site sourced from
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A-level revision resource. Fuel Cells part 2: methanolSubjects
fuel cells | green energy | methanol | chemistry | catalysts | anode | cathode | half equations | oxidation reduction | oil rig | meoh | SCIENCES and MATHEMATICS | RLicense
Attribution-Noncommercial-No Derivative Works 2.0 UK: England & Wales Attribution-Noncommercial-No Derivative Works 2.0 UK: England & Wales http://creativecommons.org/licenses/by-nc-nd/2.0/uk/ http://creativecommons.org/licenses/by-nc-nd/2.0/uk/Site sourced from
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See all metadata10.626 Electrochemical Energy Systems (MIT)
Description
10.626 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 | electrochemical energy conversion | electrochemical energy storage | transport phenomena | diffuse charge | Faradaic reactions | statistical thermodynamics | phase transformations | rechargeable batteries | fuel cells | supercapacitors | solar cells | desalination | electrokinetic energy conversionLicense
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata22.251 Systems Analysis of the Nuclear Fuel Cycle (MIT)
Description
This course provides an in-depth technical and policy analysis of various options for the nuclear fuel cycle. Topics include uranium supply, enrichment fuel fabrication, in-core physics and fuel management of uranium, thorium and other fuel types, reprocessing and waste disposal. Also covered are the principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of actinides and selected fission products in spent fuel are examined. Several state-of-the-art computer programs are provided for student use in problem sets and term papers.Subjects
nuclear fuel | nuclear fuel cycle | thorium fuel | dry recycling | transmutation | radioactive waste disposal | waste storage | nuclear waste | nuclear reactor analysis | fuel cell design | reactor design | fast reactors | breeder reactors | CANDU reactor | light water reactor | LWR | nuclear non-proliferation | plutonium recyclingLicense
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata3.014 Materials Laboratory (MIT)
Description
This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degreSubjects
electron | electronic properties | magnetism | magentic properties | structure | crystal | lattice | energy | thermodynamics | differential scanning calorimetry (DSC) | x-ray diffraction (XRD) | scanning probe microscopy (AFM | STM) | scanning electron microscopy (SEM) | UV/Vis | Raman spectroscopy | FTIR spectroscopy | x-ray photoelectron spectroscopy (XPS) | vibrating sample magnetometry (VSM) | dynamic light scattering (DLS) | phonon | quantum | quantum mechanics | radiation | battery | fuel cell | ferromagnetism | ferromagnetic | polymer | glass | corrosionLicense
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata2.60 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 utilizationSubjects
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 | 22.40License
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata10.626 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.Subjects
energy | electrochemical energy conversion | electrochemical energy storage | transport phenomena | diffuse charge | Faradaic reactions | statistical thermodynamics | phase transformations | rechargeable batteries | fuel cells | supercapacitors | solar cells | desalination | electrokinetic energy conversionLicense
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata3.014 Materials Laboratory (MIT)
Description
This course is a required sophomore subject in the Department of Materials Science and Engineering, designed to be taken in conjunction with the core lecture subject 3.012 Fundamentals of Materials Science and Engineering. The laboratory subject combines experiments illustrating the principles of quantum mechanics, thermodynamics and structure with intensive oral and written technical communication practice. Specific topics include: experimental exploration of the connections between energetics, bonding and structure of materials, and application of these principles in instruments for materials characterization; demonstration of the wave-like nature of electrons; hands-on experience with techniques to quantify energy (DSC), bonding (XPS, AES, FTIR, UV/Vis and force spectroscopy), and degreSubjects
electron | electronic properties | magnetism | magentic properties | structure | crystal | lattice | energy | thermodynamics | differential scanning calorimetry (DSC) | x-ray diffraction (XRD) | scanning probe microscopy (AFM | STM) | scanning electron microscopy (SEM) | UV/Vis | Raman spectroscopy | FTIR spectroscopy | x-ray photoelectron spectroscopy (XPS) | vibrating sample magnetometry (VSM) | dynamic light scattering (DLS) | phonon | quantum | quantum mechanics | radiation | battery | fuel cell | ferromagnetism | ferromagnetic | polymer | glass | corrosionLicense
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 https://ocw.mit.edu/terms/index.htmSite sourced from
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See all metadata3.53 Electrochemical Processing of Materials (MIT)
Description
This course covers a variety of topics concerning superconducting magnets, including thermodynamic and transport properties of aqueous and nonaqueous electrolytes, the electrode/electrolyte interface, and the kinetics of electrode processes. It also covers electrochemical characterization with regards to d.c. techniques (controlled potential, controlled current) and a.c. techniques (voltametry and impedance spectroscopy). Applications of the following will also be discussed: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells).Subjects
Thermodynamic and transport properties of aqueous and nonaqueous electrolytes | electrode/electrolyte interface | Kinetics of electrode processes | Electrochemical characterization | d.c. techniques (controlled potential | controlled current) | a.c. techniques (voltametry and impedance spectroscopy) | electrowinning | electrorefining | electroplating | electrosynthesis | electrochemical power sources (batteries and fuel cells)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 https://ocw.mit.edu/terms/index.htmSite sourced from
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