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2.57 Nano-to-Macro Transport Processes (MIT) 2.57 Nano-to-Macro Transport Processes (MIT)

Description

This course provides 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. This course provides 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 | nanoscale | nanoscale | transport phenomena | transport phenomena | photons | photons | electrons | electrons | phonons | phonons | energy carriers | energy carriers | energy transport | energy transport | heat transport | heat transport | energy levels | energy levels | statistical behavior | statistical behavior | internal energy | internal energy | waves and particles | waves and particles | scattering | scattering | heat generation | heat generation | Boltzmann equation | Boltzmann equation | classical laws | classical laws | microtechnology | microtechnology | crystal | crystal | lattice | lattice | quantum oscillator | quantum oscillator | laudaurer | laudaurer | nanotube | nanotube | Louiville equation | Louiville equation | X-ray | X-ray | blackbody | blackbody | quantum well | quantum well | Fourier | Fourier | Newton | Newton | Ohm | Ohm | thermoelectric effect | thermoelectric effect | Brownian motion | Brownian motion | surface tension | surface tension | van der Waals potential. | van der Waals potential. | van der Waals potential | van der Waals potentialLicense

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 metadata6.701 Introduction to Nanoelectronics (MIT) 6.701 Introduction to Nanoelectronics (MIT)

Description

Traditionally, progress in electronics has been driven by miniaturization. But as electronic devices approach the molecular scale, classical models for device behavior must be abandoned. To prepare for the next generation of electronic devices, this class teaches the theory of current, voltage and resistance from atoms up. To describe electrons at the nanoscale, we will begin with an introduction to the principles of quantum mechanics, including quantization, the wave-particle duality, wavefunctions and SchrÃ¶dinger's equation. Then we will consider the electronic properties of molecules, carbon nanotubes and crystals, including energy band formation and the origin of metals, insulators and semiconductors. Electron conduction will be taught beginning with ballistic transport and concludin Traditionally, progress in electronics has been driven by miniaturization. But as electronic devices approach the molecular scale, classical models for device behavior must be abandoned. To prepare for the next generation of electronic devices, this class teaches the theory of current, voltage and resistance from atoms up. To describe electrons at the nanoscale, we will begin with an introduction to the principles of quantum mechanics, including quantization, the wave-particle duality, wavefunctions and SchrÃ¶dinger's equation. Then we will consider the electronic properties of molecules, carbon nanotubes and crystals, including energy band formation and the origin of metals, insulators and semiconductors. Electron conduction will be taught beginning with ballistic transport and concludinSubjects

nanoelectronics | nanoelectronics | quantum mechanics | quantum mechanics | wave-particle duality | wave-particle duality | Schrodinger's equation | Schrodinger's equation | electronic properties of molecules | electronic properties of molecules | energy band formation | energy band formation | electron conduction | electron conduction | ballistic transport | ballistic transport | Ohm's law | Ohm's law | fundamental limits to computation | fundamental limits to computationLicense

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 metadataUCT Physics Course 1 Laboratory 2nd Semester 2011

Description

Authors: Jeff Fearon and Angus Comrie A series of pre-practical talks detailing the aims of each of five electrical experiments, and instructions on how to use the equipment. Clicked 270 times. Last clicked 07/24/2014 - 21:43. Teaching & Learning Context: The UCT Physics Course 1 Laboratory is run in parallel with and is complimentary to the main stream, calculus-based physics course PHY1004W.Subjects

Physics | Science | Video | Video Lectures | English | Post-secondary | ammeter | circuits | electrical signal generator | electricity | LRC circuit | LRC resonance | multimeter | Non-Ohmic | Ohmic | oscilloscope | RC circuit | voltmeterLicense

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Subjects

Sistema de unidades | Sistema de unidades | éctrico | éctrico | Fuerza de Lorentz | Fuerza de Lorentz | Campo de ruptura | Campo de ruptura | éctrica | éctrica | Densidad de corriente | Densidad de corriente | Ley de Gauss | Ley de Gauss | ía potencial | ía potencial | éctricos | éctricos | ón | ón | ático | ático | Fuerzas conservativas | Fuerzas conservativas | éctrico de una carga puntual | éctrico de una carga puntual | ón de la trayectoria | ón de la trayectoria | Diferencia de potencial | Diferencia de potencial | ísica Aplicada | ísica Aplicada | Trabajo | Trabajo | ético atómico | ético atómico | ática | ática | ía | ía | Fisica Aplicada | Fisica Aplicada | éticos | éticos | ética sobre corrientes | ética sobre corrientes | Distribuciones continuas de carga | Distribuciones continuas de carga | ísica Teórica | ísica Teórica | Magnetismo en la materia | Magnetismo en la materia | fuerza | fuerza | Densidades de carga | Densidades de carga | Resistencia | Resistencia | Inductancia mutua | Inductancia mutua | Movimiento circular | Movimiento circular | éticas | éticas | ética | ética | Ley de Biot y Savart | Ley de Biot y Savart | ético | ético | Concepto | Concepto | momento lineal | momento lineal | Condensadores | Condensadores | Ley de Ampere | Ley de Ampere | Ley de Lenz | Ley de Lenz | Elemento de corriente | Elemento de corriente | Autoinductancia | Autoinductancia | Ley de Ohm | Ley de Ohm | Momento angular | Momento angular | Ley de Coulomb | Ley de Coulomb | ámica de una partícula | ámica de una partícula | Momentos de fuerza sobre espiras de corriente e imanes | Momentos de fuerza sobre espiras de corriente e imanes | Fisica Teorica | Fisica Teorica | ía magnética | ía magnética | Conductores y aislantes | Conductores y aislantes | ón de Faraday | ón de Faraday | Intensidad | Intensidad | Leyes de Newton | Leyes de Newton | momento de las fuerzas | momento de las fuerzas | Fuerzas entre corrientes | Fuerzas entre corrientes | íneas de campo eléctrico | íneas de campo eléctrico | Potencia | PotenciaLicense

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See all metadataDG5434 Single Phase A.C. Circuits

Description

This unit is designed to enable learners to develop knowledge and understanding and apply basic electrical concepts and theorems to the solution of simple electrical problems. It also provides an opportunity to examine first order transient responses as found in RL and RC series circuits and to develop the necessary knowledge and skills to solve single-phase a.c. circuit problems using complex notation. Outcomes 1. Solve problems involving basic electrical concepts and theorems. 2. Solve single-phase a.c. circuit problems using complex notation.Subjects

DG54 34 | Basic electrical quantities | Circuit elements | Electromagnetic field | electrostatic fields | Ohmâ€™s law | Waveforms | series circuit | parallel circuit | Kirchhoffâ€™s laws | D.C. transients | R | L and C circuits | inductance | capacitance | Resistance | X: Engineering | ENGINEERING | SCQF Level 7License

Except where expressly indicated otherwise on the face of these materials (i) copyright in these materials is owned by the Scottish Qualification Authority (SQA), and (ii) none of these materials may be Used without the express, prior, written consent of the Colleges Open Learning Exchange Group (COLEG) and SQA, except if and to the extent that such Use is permitted under COLEG's conditions of Contribution and Use of Learning Materials through COLEGâ€™s Repository, for the purposes of which these materials are COLEG Materials. Except where expressly indicated otherwise on the face of these materials (i) copyright in these materials is owned by the Scottish Qualification Authority (SQA), and (ii) none of these materials may be Used without the express, prior, written consent of the Colleges Open Learning Exchange Group (COLEG) and SQA, except if and to the extent that such Use is permitted under COLEG's conditions of Contribution and Use of Learning Materials through COLEGâ€™s Repository, for the purposes of which these materials are COLEG Materials. Licensed to colleges in Scotland only Licensed to colleges in Scotland only http://content.resourceshare.ac.uk/xmlui/bitstream/handle/10949/17761/LicenceSQAMaterialsCOLEG.pdf?sequence=1 http://content.resourceshare.ac.uk/xmlui/bitstream/handle/10949/17761/LicenceSQAMaterialsCOLEG.pdf?sequence=1 SQA SQASite sourced from

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See all metadata2.57 Nano-to-Macro Transport Processes (MIT)

Description

This course provides 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 | nanoscale | transport phenomena | photons | electrons | phonons | energy carriers | energy transport | heat transport | energy levels | statistical behavior | internal energy | waves and particles | scattering | heat generation | Boltzmann equation | classical laws | microtechnology | crystal | lattice | quantum oscillator | laudaurer | nanotube | Louiville equation | X-ray | blackbody | quantum well | Fourier | Newton | Ohm | thermoelectric effect | Brownian motion | surface tension | van der Waals potential. | van der Waals potentialLicense

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 metadata6.701 Introduction to Nanoelectronics (MIT)

Description

Traditionally, progress in electronics has been driven by miniaturization. But as electronic devices approach the molecular scale, classical models for device behavior must be abandoned. To prepare for the next generation of electronic devices, this class teaches the theory of current, voltage and resistance from atoms up. To describe electrons at the nanoscale, we will begin with an introduction to the principles of quantum mechanics, including quantization, the wave-particle duality, wavefunctions and Schrödinger's equation. Then we will consider the electronic properties of molecules, carbon nanotubes and crystals, including energy band formation and the origin of metals, insulators and semiconductors. Electron conduction will be taught beginning with ballistic transport and concludinSubjects

nanoelectronics | quantum mechanics | wave-particle duality | Schrodinger's equation | electronic properties of molecules | energy band formation | electron conduction | ballistic transport | Ohm's law | fundamental limits to computationLicense

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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