Lessons from Nanoscience

by Mark Lundstrom

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1 [[Image(Picture1.png, 500px)]]
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3 World Scientific Publishing Company: [//www.worldscientific.com/series/lnlns Lessons from Nanoscience]
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5 Click [//www.worldscientific.com/highlight/nanosci.shtml here] for more titles in nanoscience from World Scientific Publishing Company.
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More than 50 years of research and development have created the sophisticated electronics that has shaped the world we live in. The transformation of engineering education from the practice-driven vacuum tube era to our science-driven semiconductor era played an important role in this success. Today we face new challenges in educating students, engineers, and applied scientists for a new era of electronics. Engineers will continue to need a deep understanding of their specialty, but they now also need a much broader understanding of science and technology than in the past. They need to be comfortable working from the atomic scale to the macroscale – from the materials and devices level to the system level. Lessons from Nanoscience aims to bring new approaches and new ways of thinking to electronics. The goal is to re-think the way we teach electronic materials and devices so that working from the nanoscale to the system scale is seamless and intuitive. The Lessons from Nanoscience lecture notes series is one component of an ambitious educational initiative that includes free, online short courses offered through nanoHUB-U.
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More than 50 years of research and development have created the sophisticated technologies that have shaped the world we live in. The transformation of engineering education from the practice-driven vacuum tube era to our science-driven semiconductor era played an important role in this success. Today we face new challenges in educating students, engineers, and applied scientists for a new era of electronics. Engineers will continue to need a deep understanding of their specialty, but they now also need a much broader understanding of science and technology than in the past. They need to be comfortable working from the atomic scale to the macroscale – from the materials and devices level to the system level. Lessons from Nanoscience aims to bring new approaches and new ways of thinking to materials, devices, and systems. The goal is to re-think the way we teach these topics so that working from the nanoscale to the system scale is seamless and intuitive. The Lessons from Nanoscience lecture notes series is one component of an ambitious educational initiative that includes free, online short courses offered through [https://nanohub.org/u nanoHUB-U].
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10 ===Lessons from Nanoscience Lecture Notes may:===
11 • Treat fundamental concepts in a way that seamlessly connects the nanoscale to the macroscale [[br]]
12 • Provide starting points for those just entering new fields of science or technology [[br]]
13 • Discuss techniques once restricted to specialists that are now becoming widely used. [[br]]
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15 ===Lessons from Nanoscience Lecture Notes are:===
16 • Short (150-350 pages) [[br]]
17 • Broadly accessible without a long set of pre-requisites. [[br]]
18 • Published by World Scientific in low cost paperback versions. [[br]]
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Authors who share our vision for an exciting new era of electronics driven by new approaches to education are invited to contact us with their ideas and submit a [https://nanohub.org/wiki/LessonsfromNanoscience/Prospectus Prospectus]. See [[File(one-page_flier.pdf)]]
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Authors who share our vision for an exciting new era of electronics driven by new approaches to education are invited to contact us with their ideas and submit a [https://nanohub.org/wiki/LessonsfromNanoscience/Prospectus Prospectus].
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[[File(one-page_flier.pdf)]]
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24 Mark Lundstrom and Supriyo Datta, series editors [[br]]
25 Purdue University [[br]]
26 lundstro@purdue.edu, datta@purdue.edu [[br]]
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29 ===Current Titles:===
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Supriyo Datta, Purdue University, [http://www.worldscientific.com/worldscibooks/10.1142/8029 ''Lessons from Nanoelectronics: A New Perspective on Transport'']. [https://nanohub.org/groups/lnebook "Book web page"] [[br]]
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Supriyo Datta, Purdue University, [http://www.worldscientific.com/worldscibooks/10.1142/8029 ''Lessons from Nanoelectronics: A New Perspective on Transport'']. [https://nanohub.org/wiki/LessonsfromNanoscience/ResourcesforVolume1 Book web page] [[br]]
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33 Mark S. Lundstrom and C. Jeong, Purdue University, [http://www.worldscientific.com/worldscibooks/10.1142/7975 ''Near-Equilibrium Transport: Fundamentals and Applications''] [https://nanohub.org/wiki/LessonsfromNanoscience/bookwebpage Book web page]
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35 Tim S. Fisher, Purdue University, [http://www.worldscientific.com/worldscibooks/10.1142/8716 ''Thermal Energy at the Nanoscale''] [//nanohub.org/resources/11876 Preview Lectures]
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37 Ron Reifenberger, Purdue University, [http://www.worldscientific.com/worldscibooks/10.1142/9343 ''Fundamentals of Atomic Force Microscopy, Part I: Foundations]''
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39 * Sample chapters from volumes in print are available [//nanohub.org/groups/u/lfn here] [[br]]
40 * Online courses based on these volumes are available at [//nanohub.org/u nanoHUB-U]
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43 ===Forthcoming titles in the series:===
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45 '''Fall 2016:''' Mark Lundstrom, Purdue University, ''Essential Physics of Nanoscale Transistors''
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47 '''Spring 2017:''' Muhammad Alam, Purdue University, ''Nano-biosensors: Three Easy Pieces''
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49 '''Fall 2017:''' Alejandro Strachan, Purdue University, ''Atomistic View of Materials''
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51 '''Fall 2017:''' Avik Ghosh, University of Virginia, ''Nanoelectronics: A Molecular View''
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53 '''Spring 2018:''' Jaijeet Roychowdhury, Univ. of California Berkeley, ''Developing Simulation-Ready Compact Models''
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'''Fall 2018:''' Kaustav Banerjee, Univ. of California Santa Barbara, ''Circuit Design Perspectives: the NANO approach''
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'''Spring 2018:''' Kaustav Banerjee, Univ. of California Santa Barbara, ''Circuit Design Perspectives: the NANO approach''
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'''Spring 2019:''' Tsu-Jae King Liu, Univ. of California Berkeley, ''Microdevices''
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'''Fall 2018:''' Tsu-Jae King Liu, Univ. of California Berkeley, and Nuo Xu, Samsung Semiconductors Inc., ''!FinFET Design and Applications''
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'''Spring 2019:''' Zhen Chen and Chris Dames, Univ. of California Berkeley, ''Applied Thermal Measurements at the Nanoscale''
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'''Fall 2018:''' Zhen Chen and Chris Dames, Univ. of California Berkeley, ''Applied Thermal Measurements at the Nanoscale''
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'''Fall 2019:''' Tony Low, Univ. of Minnesota, ''2D Materials Device Physics''
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'''Fall 2018:''' Babak Ziaie, ''Introduction to Neural Interfaces''
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'''Fall 2018:''' Ali Shakouri, ''Energy Conversion Devices from Nanoscale to Macroscale''
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'''Fall 2018:''' Juan Carlos Cuevas (Universidad Autónoma de Madrid), Edgar Meyhofer (University of Michigan, Ann Arbor), Pramod Reddy (University of Michigan, Ann Arbor) ''Thermal Radiation at the Nanoscale''
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Related on-line resources can be found at: [//nanohub.org/u nanoHUB-U] and [/topics/ElectronicsFromTheBottomUp Electronics from the Bottom Up]
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'''Spring 2019:''' Tony Low, Univ. of Minnesota, ''2D Materials Device Physics''
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'''Spring 2019:''' Saeed Mohammadi, Purdue University, ''Nano-Devices: From Device Modeling to Circuit and System Implementation''
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===Related on-line resources can be found at: ===
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[//nanohub.org/u nanoHUB-U] and [/topics/ElectronicsFromTheBottomUp Electronics from the Bottom Up]
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===Visit [//nanohub.org/u https://nanohub.org/u] for related online courses.===
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84 A partnership between:
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86 [[Image(ncn_nanohub_with nodes small.png, 100px, link=https://nanohub.org/groups/ncn)]] and [[Image(wspclogo.jpg, 130px, link=http://www.worldscientific.com/)]]
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