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ebook version of The tragedy of Sir Thomas Overbury: as it is acted at the Theatre-Royal in Drury-Lane, ... Written by Richard Savage, ... ebook version of The tragedy of Sir Thomas Overbury: as it is acted at the Theatre-Royal in Drury-Lane, ... Written by Richard Savage, ...License

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ebook version of Clementina: a tragedy, as it is perform'd with universal applause at the Theatre-Royal in Covent-Garden. ebook version of Clementina: a tragedy, as it is perform'd with universal applause at the Theatre-Royal in Covent-Garden.License

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ebook version of The non-juror: A comedy. As it is acted at the Theatre-Royal, by His Majesty's servants. Writien [sic] by Mr. Cibber. ebook version of The non-juror: A comedy. As it is acted at the Theatre-Royal, by His Majesty's servants. Writien [sic] by Mr. Cibber.License

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ebook version of The camp: a musical entertainment, as performed at the Theatre Royal, Drury Lane. By R. B. Sheridan, Esq. ebook version of The camp: a musical entertainment, as performed at the Theatre Royal, Drury Lane. By R. B. Sheridan, Esq.License

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ebook version of The school for scandal: a comedy; as it is performed at the Theatres-Royal, in London and Dublin. ebook version of The school for scandal: a comedy; as it is performed at the Theatres-Royal, in London and Dublin.License

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ebook version of The poor soldier: a comic opera. In two acts. With all the original songs. Written by John O'Keefe, Esq; ... As acted at the Theatre-Royal, Covent Garden. ebook version of The poor soldier: a comic opera. In two acts. With all the original songs. Written by John O'Keefe, Esq; ... As acted at the Theatre-Royal, Covent Garden.License

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ebook version of The harlot's progress; or, the ridotto al'fresco: a grotesque pantomime entertainment. As it is perform'd by his Majesty's Company of comedians at the Theatre-Royal in Drury-Lane. Compos'd by Mr. Theophilus Cibber, ... The songs made (to old ballad tunes) by a friend. ebook version of The harlot's progress; or, the ridotto al'fresco: a grotesque pantomime entertainment. As it is perform'd by his Majesty's Company of comedians at the Theatre-Royal in Drury-Lane. Compos'd by Mr. Theophilus Cibber, ... The songs made (to old ballad tunes) by a friend.License

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See all metadataLecture 2: Work, heat, first law Lecture 2: Work, heat, first law

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Topics covered: Work, heat, first law Instructor/speaker: Moungi Bawendi, Keith Nelson Transcript: PDFSubtitles: SRTThumbnail - JPG (OCW)Video - download: Internet Archive (MP4)Video - download: iTunes U (MP4)Video - stream: VideoLectures.net Video - stream: YouTube (CC BY-NC-SA) Topics covered: Work, heat, first law Instructor/speaker: Moungi Bawendi, Keith Nelson Transcript: PDFSubtitles: SRTThumbnail - JPG (OCW)Video - download: Internet Archive (MP4)Video - download: iTunes U (MP4)Video - stream: VideoLectures.net Video - stream: YouTube (CC BY-NC-SA)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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See all metadata2.57 Nano-to-Macro Transport Processes (MIT) 2.57 Nano-to-Macro Transport Processes (MIT)

Description

Includes audio/video content: AV lectures. Parallel treatments of photons, electrons, phonons, and molecules as energy carriers, aiming at fundamental understanding and descriptive tools for energy and heat transport processes from nanoscale continuously to macroscale. Topics include the energy levels, the statistical behavior and internal energy, energy transport in the forms of waves and particles, scattering and heat generation processes, Boltzmann equation and derivation of classical laws, deviation from classical laws at nanoscale and their appropriate descriptions, with applications in nano- and microtechnology. Includes audio/video content: AV lectures. Parallel treatments of photons, electrons, phonons, and molecules as energy carriers, aiming at fundamental understanding and descriptive tools for energy and heat transport processes from nanoscale continuously to macroscale. Topics include the energy levels, the statistical behavior and internal energy, energy transport in the forms of waves and particles, scattering and heat generation processes, Boltzmann equation and derivation of classical laws, deviation from classical laws at nanoscale and their appropriate descriptions, with applications in nano- and microtechnology.Subjects

nanotechnology | nanotechnology | nanostructure | nanostructure | energy | energy | energy transport | energy transport | energy storage | energy storage | energy carriers | energy carriers | quantum mechanics | quantum mechanics | quantum physics | quantum physics | thermoelectrics | thermoelectrics | semiconductor physics | semiconductor physics | solar cells | solar cells | waves and particles | waves and particlesLicense

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 metadata22.091 Nuclear Reactor Safety (MIT) 22.091 Nuclear Reactor Safety (MIT)

Description

Problems in nuclear engineering often involve applying knowledge from many disciplines simultaneously in achieving satisfactory solutions. The course will focus on understanding the complete nuclear reactor system including the balance of plant, support systems and resulting interdependencies affecting the overall safety of the plant and regulatory oversight. Both the Seabrook and Pilgrim nuclear plant simulators will be used as part of the educational experience to provide as realistic as possible understanding of nuclear power systems short of being at the reactor. Problems in nuclear engineering often involve applying knowledge from many disciplines simultaneously in achieving satisfactory solutions. The course will focus on understanding the complete nuclear reactor system including the balance of plant, support systems and resulting interdependencies affecting the overall safety of the plant and regulatory oversight. Both the Seabrook and Pilgrim nuclear plant simulators will be used as part of the educational experience to provide as realistic as possible understanding of nuclear power systems short of being at the reactor.Subjects

nuclear | nuclear | reactor | reactor | safety | safety | dryout heat flux | dryout heat flux | preexisting hydrogen | preexisting hydrogen | blowdown gases | blowdown gases | downward propagation limit | downward propagation limit | debris dispersal | debris dispersal | direct containment heating | direct containment heating | gas blowthrough | gas blowthrough | seal table room | seal table room | subcompartment structures | subcompartment structures | compartmentalized geometries | compartmentalized geometries | overlying liquid layer | overlying liquid layer | preexisting atmosphere | preexisting atmosphere | blowdown time | blowdown time | melt generator | melt generator | detonation adiabatic | detonation adiabatic | thermohydraulic codes | thermohydraulic codes | hydrodynamic fragmentation | hydrodynamic fragmentation | vent clearing | vent clearing | combustion completeness | combustion completeness | containment pressurization | containment pressurization | melt retention | melt retention | containment loads | containment loads | melt ejection | melt ejection | containment geometry | containment geometry | hole ablation | hole ablation | Sandia National Laboratories | Sandia National Laboratories | Heat Transfer Conf | Heat Transfer Conf | Nuclear Regulatory Commission Report | Nuclear Regulatory Commission Report | Heat Mass Transfer | Heat Mass Transfer | The Combustion Institute | The Combustion Institute | Combustion Symposium International | Combustion Symposium International | New York | New York | Santa Barbara | Santa Barbara | Argonne National Laboratory | Argonne National Laboratory | Fluid Mech | Fluid Mech | Zion Probabilistic Safety Study | Zion Probabilistic Safety Study | Los Angeles | Los Angeles | Impact of Hydrogen | Impact of Hydrogen | Topical Meeting | Topical Meeting | Water Reactor Safety | Water Reactor Safety | Water Trans | Water Trans | Academic Press All | Academic Press All | American Society of Mechanical Engineers | American Society of Mechanical Engineers | Specialists Meeting | Specialists Meeting | University of California | University of California | Brookhaven National Laboratory | Brookhaven National Laboratory | Calvert Cliffs | Calvert Cliffs | Fourth Int | Fourth Int | International Conference | International Conference | New Trends. | New Trends.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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Includes audio/video content: AV lectures. This course introduces principles and technologies for converting heat into electricity via solid-state devices. The first part of the course discusses thermoelectric energy conversion and thermoelectric materials, thermionic energy conversion, and photovoltaics. The second part of the course discusses solar thermal technologies. Various solar heat collection systems will be reviewed, followed by an introduction to the principles of solar thermophotovoltaics and solar thermoelectrics. Spectral control techniques, which are critical for solar thermal systems, will be discussed. Includes audio/video content: AV lectures. This course introduces principles and technologies for converting heat into electricity via solid-state devices. The first part of the course discusses thermoelectric energy conversion and thermoelectric materials, thermionic energy conversion, and photovoltaics. The second part of the course discusses solar thermal technologies. Various solar heat collection systems will be reviewed, followed by an introduction to the principles of solar thermophotovoltaics and solar thermoelectrics. Spectral control techniques, which are critical for solar thermal systems, will be discussed.Subjects

thermophotovoltaics | thermophotovoltaics | thermoelectric devices | thermoelectric devices | selective surfaces | selective surfaces | nanostructured materials | nanostructured materials | photovoltaic cells | photovoltaic cells | semiconductor physics | semiconductor physics | phonons | phonons | absorption spectrum | absorption spectrum | Seebeck effect | Seebeck effect | thermionic engines | thermionic engines | photonic crystals | photonic crystals | band gap | band gapLicense

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 metadata6.642 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 solutionSubjects

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 dynamicsLicense

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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Includes audio/video content: AV lectures. This graduate-level course is a continuation of Mathematical Methods for Engineers I (18.085). Topics include numerical methods; initial-value problems; network flows; and optimization. Includes audio/video content: AV lectures. This graduate-level course is a continuation of Mathematical Methods for Engineers I (18.085). Topics include numerical methods; initial-value problems; network flows; and optimization.Subjects

Scientific computing: Fast Fourier Transform | Scientific computing: Fast Fourier Transform | finite differences | finite differences | finite elements | finite elements | spectral method | spectral method | numerical linear algebra | numerical linear algebra | Complex variables and applications | Complex variables and applications | Initial-value problems: stability or chaos in ordinary differential equations | Initial-value problems: stability or chaos in ordinary differential equations | wave equation versus heat equation | wave equation versus heat equation | conservation laws and shocks | conservation laws and shocks | dissipation and dispersion | dissipation and dispersion | Optimization: network flows | Optimization: network flows | linear programming | linear programming | Scientific computing: Fast Fourier Transform | finite differences | finite elements | spectral method | numerical linear algebra | Scientific computing: Fast Fourier Transform | finite differences | finite elements | spectral method | numerical linear algebra | Initial-value problems: stability or chaos in ordinary differential equations | wave equation versus heat equation | conservation laws and shocks | dissipation and dispersion | Initial-value problems: stability or chaos in ordinary differential equations | wave equation versus heat equation | conservation laws and shocks | dissipation and dispersion | Optimization: network flows | linear programming | Optimization: network flows | linear programmingLicense

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 sophomore-level course is a project-oriented introduction to the principles and practice of engineering design. Design projects and exercises are chosen that relate to the built and natural environments. Emphasis is placed on achieving function and sustainability through choice of materials and processes, compatibility with natural cycles, and the use of active or adaptive systems. The course also encourages development of hands-on skills, teamwork, and communication; exercises and projects engage students in the building, implementation, and testing of their designs. This sophomore-level course is a project-oriented introduction to the principles and practice of engineering design. Design projects and exercises are chosen that relate to the built and natural environments. Emphasis is placed on achieving function and sustainability through choice of materials and processes, compatibility with natural cycles, and the use of active or adaptive systems. The course also encourages development of hands-on skills, teamwork, and communication; exercises and projects engage students in the building, implementation, and testing of their designs.Subjects

Design | Design | water resources | water resources | water treatment | water treatment | structures | structures | structural design | structural design | fabrication | fabrication | testing | testing | hardware | hardware | laboratory experiments | laboratory experiments | pH | pH | neutralization | neutralization | hydraulic conductivity | hydraulic conductivity | porosity | porosity | truss | truss | tension | tension | beam bending | beam bending | beam buckling | beam buckling | thermal design | thermal design | heating | heating | cooling | cooling | thermal infrared camera | thermal infrared camera | thermal IR imaging | thermal IR imaging | heat loss | heat lossLicense

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 presents finite element theory and methods for general linear and nonlinear analyses. Reliable and effective finite element procedures are discussed with their applications to the solution of general problems in solid, structural, and fluid mechanics, heat and mass transfer, and fluid-structure interactions. The governing continuum mechanics equations, conservation laws, virtual work, and variational principles are used to establish effective finite element discretizations and the stability, accuracy, and convergence are discussed. The homework and the student-selected term project using the general-purpose finite element analysis program ADINA are important parts of the course. This course presents finite element theory and methods for general linear and nonlinear analyses. Reliable and effective finite element procedures are discussed with their applications to the solution of general problems in solid, structural, and fluid mechanics, heat and mass transfer, and fluid-structure interactions. The governing continuum mechanics equations, conservation laws, virtual work, and variational principles are used to establish effective finite element discretizations and the stability, accuracy, and convergence are discussed. The homework and the student-selected term project using the general-purpose finite element analysis program ADINA are important parts of the course.Subjects

linear static analysis | linear static analysis | solids | solids | structures | structures | nonlinear static analysis | nonlinear static analysis | heat transfer | heat transfer | fluid flows | fluid flows | finite element methods | finite element methods | ADINA | ADINA | student work | student work | beams | beams | plates | plates | shells | shells | displacement | displacement | conduction | conduction | convection | convection | radiation | radiation | Navier-Stokes | Navier-Stokes | incompressible fluids | incompressible fluids | acoustic fluids | acoustic fluidsLicense

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 introduces finite element methods for the analysis of solid, structural, fluid, field, and heat transfer problems. Steady-state, transient, and dynamic conditions are considered. Finite element methods and solution procedures for linear and nonlinear analyses are presented using largely physical arguments. The homework and a term project (for graduate students) involve use of the general purpose finite element analysis program ADINA. Applications include finite element analyses, modeling of problems, and interpretation of numerical results. This course introduces finite element methods for the analysis of solid, structural, fluid, field, and heat transfer problems. Steady-state, transient, and dynamic conditions are considered. Finite element methods and solution procedures for linear and nonlinear analyses are presented using largely physical arguments. The homework and a term project (for graduate students) involve use of the general purpose finite element analysis program ADINA. Applications include finite element analyses, modeling of problems, and interpretation of numerical results.Subjects

finite element methods | finite element methods | solids | solids | structures | structures | fluid mechanics | fluid mechanics | heat transfer | heat transfer | equilibrium equations | equilibrium equations | direct integration | direct integration | mode superposition | mode superposition | eigensolution techniques | eigensolution techniques | frequencies | frequencies | mode shapes | mode shapes | statics | statics | dynamics | dynamics | nonlinear systems | nonlinear systems | wave propagation | wave propagationLicense

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 metadata2.61 Internal Combustion Engines (MIT) 2.61 Internal Combustion Engines (MIT)

Description

This course studies the fundamentals of how the design and operation of internal combustion engines affect their performance, operation, fuel requirements, and environmental impact. Topics include fluid flow, thermodynamics, combustion, heat transfer and friction phenomena, and fuel properties, with reference to engine power, efficiency, and emissions. Students examine the design features and operating characteristics of different types of internal combustion engines: spark-ignition, diesel, stratified-charge, and mixed-cycle engines. Class includes lab project in the Engine Laboratory. This course studies the fundamentals of how the design and operation of internal combustion engines affect their performance, operation, fuel requirements, and environmental impact. Topics include fluid flow, thermodynamics, combustion, heat transfer and friction phenomena, and fuel properties, with reference to engine power, efficiency, and emissions. Students examine the design features and operating characteristics of different types of internal combustion engines: spark-ignition, diesel, stratified-charge, and mixed-cycle engines. Class includes lab project in the Engine Laboratory.Subjects

internal combustion engines | internal combustion engines | engine operation | engine operation | engine fuel requirements | engine fuel requirements | environmental impact | environmental impact | fluid flow | thermodynamics | combustion | heat transfer and friction phenomena | fluid flow | thermodynamics | combustion | heat transfer and friction phenomena | fuel properties | fuel properties | power | power | efficiency | efficiency | emissions | emissions | spark-ignition | spark-ignition | diesel | diesel | stratified-charge | stratified-charge | mixed-cycle engine | mixed-cycle engine | full lecture notes | full lecture notesLicense

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 metadata2.58J Radiative Transfer (MIT) 2.58J Radiative Transfer (MIT)

Description

This course investigates the principles of thermal radiation and their applications to engineering heat and photon transfer problems. Topics include quantum and classical models of radiative properties of materials, electromagnetic wave theory for thermal radiation, radiative transfer in absorbing, emitting, and scattering media, and coherent laser radiation. Applications cover laser-material interactions, imaging, infrared instrumentation, global warming, semiconductor manufacturing, combustion, furnaces, and high temperature processing. This course investigates the principles of thermal radiation and their applications to engineering heat and photon transfer problems. Topics include quantum and classical models of radiative properties of materials, electromagnetic wave theory for thermal radiation, radiative transfer in absorbing, emitting, and scattering media, and coherent laser radiation. Applications cover laser-material interactions, imaging, infrared instrumentation, global warming, semiconductor manufacturing, combustion, furnaces, and high temperature processing.Subjects

thermal radiation | thermal radiation | heat transfer | heat transfer | photon transfer | photon transfer | quantum modeling | quantum modeling | materials | materials | electromagnetic | electromagnetic | absorption | absorption | emitting media | emitting media | scattering | scattering | laser | laser | imaging | imaging | infrared | infrared | global warming | global warming | semiconductor manufacturing | semiconductor manufacturing | combustion | combustion | furnace | furnace | high temperature processing | high temperature processing | Drude | Drude | Lorenz | Lorenz | gas | gas | dielectric | dielectric | Monte Carlo | Monte Carlo | simulation | simulation | solar energy | solar energy | solar power | solar power | solar cell | solar cell | 2.58 | 2.58 | 10.74 | 10.74License

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 metadata3.012 Fundamentals of Materials Science (MIT) 3.012 Fundamentals of Materials Science (MIT)

Description

This course focuses on the fundamentals of structure, energetics, and bonding that underpin materials science. It is the introductory lecture class for sophomore students in Materials Science and Engineering, taken with 3.014 and 3.016 to create a unified introduction to the subject. Topics include: an introduction to thermodynamic functions and laws governing equilibrium properties, relating macroscopic behavior to atomistic and molecular models of materials; the role of electronic bonding in determining the energy, structure, and stability of materials; quantum mechanical descriptions of interacting electrons and atoms; materials phenomena, such as heat capacities, phase transformations, and multiphase equilibria to chemical reactions and magnetism; symmetry properties of molecules and s This course focuses on the fundamentals of structure, energetics, and bonding that underpin materials science. It is the introductory lecture class for sophomore students in Materials Science and Engineering, taken with 3.014 and 3.016 to create a unified introduction to the subject. Topics include: an introduction to thermodynamic functions and laws governing equilibrium properties, relating macroscopic behavior to atomistic and molecular models of materials; the role of electronic bonding in determining the energy, structure, and stability of materials; quantum mechanical descriptions of interacting electrons and atoms; materials phenomena, such as heat capacities, phase transformations, and multiphase equilibria to chemical reactions and magnetism; symmetry properties of molecules and sSubjects

bonding | bonding | energetics | energetics | structure | structure | antibonding | antibonding | hydrogen | hydrogen | Quantum mechanics | Quantum mechanics | electron | electron | atom | atom | molecule | molecule | molecular dynamics | molecular dynamics | MD | MD | Symmetry properties | Symmetry properties | solid | solid | gas | gas | liquid | liquid | phase | phase | matter; molecular geometry | matter; molecular geometry | complex and disordered materials | complex and disordered materials | thermodynamics | thermodynamics | equilibrium property | equilibrium property | macroscopic behavior | macroscopic behavior | molecular model | molecular model | heat capacity | heat capacity | phase transformation | phase transformation | multiphase equilibria | multiphase equilibria | chemical reaction | chemical reaction | magnetism | magnetism | engineered alloy | engineered alloy | electronic and magnetic material | electronic and magnetic material | ionic solid | ionic solid | network solid | network solid | polymer | polymer | biomaterial | biomaterial | glass | glass | liquid crystal | liquid crystal | LCD | LCD | matter | matter | molecular geometry | molecular geometryLicense

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 metadata3.37 Welding and Joining Processes (MIT) 3.37 Welding and Joining Processes (MIT)

Description

Discusses a wide variety of processes and materials from the viewpoint of their fundamental physical and chemical properties. Specific topics: cold welding, adhesive bonding, diffusion bonding, soldering, brazing, flames, arcs, high-energy density heat sources, solidification, cracking resistance, shielding methods, and electric contacts. Emphasis on underlying science of a given process rather than a detailed description of the technique or equipment. This course meets with the first half of 3.371J in the Fall Term. Discusses a wide variety of processes and materials from the viewpoint of their fundamental physical and chemical properties. Specific topics: cold welding, adhesive bonding, diffusion bonding, soldering, brazing, flames, arcs, high-energy density heat sources, solidification, cracking resistance, shielding methods, and electric contacts. Emphasis on underlying science of a given process rather than a detailed description of the technique or equipment. This course meets with the first half of 3.371J in the Fall Term.Subjects

cold welding | cold welding | adhesive bonding | adhesive bonding | diffusion bonding | diffusion bonding | soldering | soldering | brazing | brazing | flames | flames | arcs | arcs | high-energy density heat sources | high-energy density heat sources | solidification | solidification | cracking resistance | cracking resistance | shielding methods | shielding methods | electric contacts | electric contactsLicense

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 metadata6.730 Physics for Solid-State Applications (MIT) 6.730 Physics for Solid-State Applications (MIT)

Description

This course examines classical and quantum models of electrons and lattice vibrations in solids, emphasizing physical models for elastic properties, electronic transport, and heat capacity. Topics covered include: crystal lattices, electronic energy band structures, phonon dispersion relatons, effective mass theorem, semiclassical equations of motion, and impurity states in semiconductors, band structure and transport properties of selected semiconductors, and connection of quantum theory of solids with quasifermi levels and Boltzmann transport used in device modeling. This course examines classical and quantum models of electrons and lattice vibrations in solids, emphasizing physical models for elastic properties, electronic transport, and heat capacity. Topics covered include: crystal lattices, electronic energy band structures, phonon dispersion relatons, effective mass theorem, semiclassical equations of motion, and impurity states in semiconductors, band structure and transport properties of selected semiconductors, and connection of quantum theory of solids with quasifermi levels and Boltzmann transport used in device modeling.Subjects

physics | physics | solid state application | solid state application | quantum model | quantum model | electron | electron | lattice vibration | lattice vibration | electronic transport | electronic transport | heat capacity | heat capacity | elastic properties | elastic properties | cystal lattice | cystal lattice | electronic energy band | electronic energy band | phonon dispersion relatons | phonon dispersion relatons | effective mass theorem | effective mass theorem | motion equation | motion equation | impurity state | impurity state | semiconductor | semiconductor | band structure | band structure | transport properties | transport properties | quantum theory of solids | quantum theory of solids | quasifermi | quasifermi | Boltzmann transport | Boltzmann transport | device modeling | device modelingLicense

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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Bacteria survive in almost all environments on Earth, including some considered extremely harsh. From the steaming hot springs of Yellowstone to the frozen tundra of the arctic to the barren deserts of Chile, microbes have been found thriving. Their tenacity to survive in such extreme and varied conditions allows them to play fundamental roles in global nutrient cycling. Microbes also cause a wide range of human diseases and can survive inhospitable conditions found in the human body. In this course, we will examine the molecular systems that bacteria use to adapt to changes in their environment. We will consider stresses commonly encountered, such as starvation, oxidative stress and heat shock, and also discuss how the adaptive responses affect the evolution of the bacteria. This course Bacteria survive in almost all environments on Earth, including some considered extremely harsh. From the steaming hot springs of Yellowstone to the frozen tundra of the arctic to the barren deserts of Chile, microbes have been found thriving. Their tenacity to survive in such extreme and varied conditions allows them to play fundamental roles in global nutrient cycling. Microbes also cause a wide range of human diseases and can survive inhospitable conditions found in the human body. In this course, we will examine the molecular systems that bacteria use to adapt to changes in their environment. We will consider stresses commonly encountered, such as starvation, oxidative stress and heat shock, and also discuss how the adaptive responses affect the evolution of the bacteria. This courseSubjects

bacteria | bacteria | microbes | microbes | signal transduction pathways | signal transduction pathways | cellular response | cellular response | model systems | model systems | Escherichia coli | Escherichia coli | Bacillus subtilis | Bacillus subtilis | oxidative stress | oxidative stress | starvation | starvation | heat shock | heat shock | dormant state | dormant state | microbial stress response | microbial stress response | bacterial genetics | bacterial genetics | microbiology | microbiology | sporulation | sporulation | sRNAs | sRNAs | histidine kinases | histidine kinases | response regulators | response regulators | mRNAs | mRNAs | RpoS | RpoS | small molecules | small molecules | efflux pumps | efflux pumps | Pseudomonas aeruginosa | Pseudomonas aeruginosaLicense

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In the ICE-Topics courses, various chemical engineering problems are presented and analyzed in an industrial context. Emphasis is on the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies.The broad context for this ICE-Topics module is the commonsense notion that, when designing something, one should plan for the off-normal conditions that may occur. A continuous process is conceived and designed as a steady-state operation. However, the process must start up, shut down, and operate in the event of disturbances, and so the time-varying b In the ICE-Topics courses, various chemical engineering problems are presented and analyzed in an industrial context. Emphasis is on the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies.The broad context for this ICE-Topics module is the commonsense notion that, when designing something, one should plan for the off-normal conditions that may occur. A continuous process is conceived and designed as a steady-state operation. However, the process must start up, shut down, and operate in the event of disturbances, and so the time-varying bSubjects

process control | process control | heat exchanger network | heat exchanger network | design | design | shower process | shower process | continuous chemical processes | continuous chemical processes | dynamic simulation | dynamic simulation | implementation | implementation | controllers | controllers | feedback structure | feedback structure | material model | material model | energy balance model | energy balance model | linearizing equations | linearizing equations | Relative Gain Array | Relative Gain Array | Disturbance Cost | Disturbance Cost | proportional control algorithm | proportional control algorithm | steady-state model | steady-state model | numerical linearization | numerical linearization | matrix operations | matrix operations | variable pairing | variable pairing | process simulators | process simulators | design process | design process | offset phenomenon | offset phenomenon | RGA | RGA | DC | DC | heat recovery scheme | heat recovery schemeLicense

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 metadata16.13 Aerodynamics of Viscous Fluids (MIT) 16.13 Aerodynamics of Viscous Fluids (MIT)

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The major focus of 16.13 is on boundary layers, and boundary layer theory subject to various flow assumptions, such as compressibility, turbulence, dimensionality, and heat transfer. Parameters influencing aerodynamic flows and transition and influence of boundary layers on outer potential flow are presented, along with associated stall and drag mechanisms. Numerical solution techniques and exercises are included. The major focus of 16.13 is on boundary layers, and boundary layer theory subject to various flow assumptions, such as compressibility, turbulence, dimensionality, and heat transfer. Parameters influencing aerodynamic flows and transition and influence of boundary layers on outer potential flow are presented, along with associated stall and drag mechanisms. Numerical solution techniques and exercises are included.Subjects

aerodynamics | aerodynamics | viscous fluids | viscous fluids | viscosity | viscosity | fundamental theorem of kinematics | fundamental theorem of kinematics | convection | convection | vorticity | vorticity | strain | strain | Eulerian description | Eulerian description | Lagrangian description | Lagrangian description | conservation of mass | conservation of mass | continuity | continuity | conservation of momentum | conservation of momentum | stress tensor | stress tensor | newtonian fluid | newtonian fluid | circulation | circulation | Navier-Stokes | Navier-Stokes | similarity | similarity | dimensional analysis | dimensional analysis | thin shear later approximation | thin shear later approximation | TSL coordinates | TSL coordinates | boundary conditions | boundary conditions | shear later categories | shear later categories | local scaling | local scaling | Falkner-Skan flows | Falkner-Skan flows | solution techniques | solution techniques | finite difference methods | finite difference methods | Newton-Raphson | Newton-Raphson | integral momentum equation | integral momentum equation | Thwaites method | Thwaites method | integral kinetic energy equation | integral kinetic energy equation | dissipation | dissipation | asymptotic perturbation | asymptotic perturbation | displacement body | displacement body | transpiration | transpiration | form drag | form drag | stall | stall | interacting boundary layer theory | interacting boundary layer theory | stability | stability | transition | transition | small-perturbation | small-perturbation | Orr-Somemerfeld | Orr-Somemerfeld | temporal amplification | temporal amplification | spatial amplification | spatial amplification | Reynolds | Reynolds | Prandtl | Prandtl | turbulent boundary layer | turbulent boundary layer | wake | wake | wall layers | wall layers | inner variables | inner variables | outer variables | outer variables | roughness | roughness | Clauser | Clauser | Dissipation formula | Dissipation formula | integral closer | integral closer | turbulence modeling | turbulence modeling | transport models | transport models | turbulent shear layers | turbulent shear layers | compressible then shear layers | compressible then shear layers | compressibility | compressibility | temperature profile | temperature profile | heat flux | heat flux | 3D boundary layers | 3D boundary layers | crossflow | crossflow | lateral dilation | lateral dilation | 3D separation | 3D separation | constant-crossflow | constant-crossflow | 3D transition | 3D transition | compressible thin shear layers | compressible thin shear layersLicense

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See all metadata16.20 Structural Mechanics (MIT) 16.20 Structural Mechanics (MIT)

Description

Applies solid mechanics to analysis of high-technology structures. Structural design considerations. Review of three-dimensional elasticity theory; stress, strain, anisotropic materials, and heating effects. Two-dimensional plane stress and plane strain problems. Torsion theory for arbitrary sections. Bending of unsymmetrical section and mixed material beams. Bending, shear, and torsion of thin-wall shell beams. Buckling of columns and stability phenomena. Introduction to structural dynamics. Exercises in the design of general and aerospace structures. Applies solid mechanics to analysis of high-technology structures. Structural design considerations. Review of three-dimensional elasticity theory; stress, strain, anisotropic materials, and heating effects. Two-dimensional plane stress and plane strain problems. Torsion theory for arbitrary sections. Bending of unsymmetrical section and mixed material beams. Bending, shear, and torsion of thin-wall shell beams. Buckling of columns and stability phenomena. Introduction to structural dynamics. Exercises in the design of general and aerospace structures.Subjects

solid mechanics | solid mechanics | high-technology structures | high-technology structures | Structural design considerations | Structural design considerations | three-dimensional elasticity theory | three-dimensional elasticity theory | stress | stress | strain | strain | anisotropic materials | anisotropic materials | heating effects | heating effects | torsion theory | torsion theory | Bending | Bending | shear | shear | Buckling | Buckling | stability phenomena | stability phenomena | structural dynamics | structural dynamicsLicense

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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