Rogers, Jesse Adams--both with a Nevada nanotechnology company--and Sumita Pennathur (mechanical engineering, U. of California-Santa Barbara) present a textbook introducing nanotechnology to students in any of the fields that contribute to it: physics, chemistry, biology, and engineering. They cover the big picture and principles of the small world, miniaturization, nanoscale physics, nanomaterials, nanomechanics, nanoelectronics, manoscale heat transfer, nanophotonics, nanoscale fluid mechanics, and nanobiotechnology. Annotation ©2011 Book News, Inc., Portland, OR (booknews.com)
Winner of a CHOICE Outstanding Academic Book Award 2011!
Transistors using one electron at a time. Sunscreens made with titanium dioxide particles that look transparent to our eyes but block harmful UV rays. Nanometer-sized specks of gold that change color to red and melt at 750°C instead of 1064°C. Nanotechnology takes the unique physical properties of items measuring roughly 0.1 to 1000 nanometers and puts them to use.
Such applications have made nanotechnology a hot topic, but the search for a true introductory resource usually comes up cold. Nano novices come from a wide variety of backgrounds, so an effective text must assume limited understanding of background material and not be overly focused on any particular area. Still, it must maintain scientific rigor and quality.
Fitting neatly between popular science books and high-level treatises,Nanotechnology: Understanding Small Systems, Second Edition works from the ground up to provide:
- A detailed yet accessible introduction to one of the world’s fastest growing fields, understandable to members of a variety of disciplines
- A clear presentation of real-world examples and original illustrations, as well as hundreds of homework problems of varying types, including multiple choice, true-false, in-depth calculation, and essay (with complete solutions manual)
- A systems-based approach that illustrates how underlying areas of nano are assembled to create systems with unique functions and characteristics
Comparing nanoscale and macroscale systems reveals the complex and fundamental differences between phenomena at different scales and uncovers the specific challenges and opportunities of nano. With its engaging and entertaining style, this book provides a gateway into an exciting and rapidly evolving area of science.
Arvustused
"Ever since Richard Feynman gave his classic talk in 1959, "There Is Plenty of Room at the Bottom," there has been a steadily increasing buzz in manipulating matter at the atomic scale--nanotechnology. This updated work (1st ed., 2008) takes the revolutionary concepts and techniques that have traditionally been fodder for graduate study and makes them accessible for all. Covering subjects ranging from materials science to mechanics and biotechnology to photonics, Rogers and Adams (both, Nevada Nano) and Pennathur (Univ. of California, Santa Barbara) deftly introduce the reader to each topic and quickly explain why it is important on the nanoscale. An exciting feature is the 'back of the envelope' examples, where the reader is walked through 'quick and dirty' calculations to illustrate and understand (mathematically) the complex concepts discussed. The end of each chapter includes traditional problem sets and short answer questions to test understanding. While not a comprehensive text in any specific area of nanoscale science or engineering, this outstanding introduction to the broad field of nanotechnology provides a solid foundation for further study. Summing Up: Highly recommended. Lower-division undergraduates and above; general readers." N.M. Fahrenkopf, University at Albany, CHOICE, 2011
Praise for the First Edition "It is written in an easily understandable manner, not requiring from the reader deep knowledge in the related topics of physics and mathematics before reading this book. It uncovers the most important things about nanotechnology explained in a very illustrative manner with many simple examples, figures, and `back-of-the-envelope calculations, so that the reader can get a good feeling for the numbers of nanotechnology." Zentralblatt MATH, 1185
Big Picture and Principles of the Small World
Understanding the Atom: Ex Nihilo Nihil Fit
Nanotechnology Starts with a Dare: Feynmans Big Little Challenges
Why One-Billionth of a Meter Is a Big Deal
Thinking It Through: The Broad Implications of Nanotechnology
The Business of Nanotech: Plenty of Room at the Bottom Line Too
Introduction to Miniaturization
Background: The Smaller, the Better
Scaling Laws
Accuracy of the Scaling Laws
Introduction to Nanoscale Physics
Background: Newton Never Saw a Nanotube
One Hundred Hours and Eight Minutes of Nanoscale Physics
The Basics of Quantum Mechanics
Nanomaterials
Background: Matter Matters
Bonding Atoms to Make Molecules and Solids
Crystal Structures
Structures Small Enough to Be Different (and Useful)
Nanomechanics
Background: The Universe Mechanism
A High-Speed Review of Motion: Disp lacement, Velocity, Acceleration, and
Force
Nanomechanical Oscillators: A Tale of Beams and Atoms
Feeling Faint Forces
Nanoelectronics
Background: The Problem (Opportunity)
Electron Energy Bands
Electrons in Solids: Conductors, Insulators, and Semiconductors
Fermi Energy
The Density of States for Solids
Turn Down the Volume! (How to Make a Solid Act More Like an Atom)
Quantum Confinement
Tunneling
Single Electron Phenomena
Molecular Electronics
Nanoscale Heat Transfer
Background: Hot Topic
All Heat Is Nanoscale Heat
Conduction
Convection
Radiation
Nanophotonics
Background: The Lycurgus Cup and the birth of the Photon
Photonic Properties of Nanomaterials
Near-Field Light
Optical Tweezers
Photonic Crystals: A Band Gap for Photons
Nanoscale Fluid Mechanics
Background: Becoming Fluent in Fluids
Fluids at the Nanoscale: Major Concepts
How Fluids Flow at the Nanoscale
Applications of Nanofluidics
Nanobiotechnology
Background: Our World in a Cell
Introduction: How Biology "Feels" at the Nanometer Scale
The Machinery of the Cell
Applications of Nanobiotechnology
Ben Rogers graduated Cum Laude with a Bachelor of Science in Mechanical Engineering (2001) and a Master of Science in Mechanical Engineering (2002), from the University of Nevada, Reno. He's worked on a due diligence team to evaluate and mentor start-up companies, and as a staff writer for multiple newspapers.. More recently, he's worked as a research scientist at Nanogen, Inc., the Oak Ridge National Laboratory, the NASA Jet Propulsion Laboratory, and the Nanomechanics Research Group at the University of Nevada. He's coauthored 19 technical papers in journals including Nature and Applied Physics Letters, has two patents and has served as a reviewer for both scientific and educational journals, as well as the National Science Foundation. He is the lead author of Nanotechnology: Understanding Small Systems (CRC Press), a first-of-its kind, comprehensive textbook on nanotechnology, and teaches a course on the topic. Ben currently serves as the principal engineer at Nevada Nanotech Systems, Inc., working to commercialize a new sensor technology. He lives in Reno with his wife and two daughters. In his spare time, he loves to write and has published a novel as well as many short stories and essays.
Professor Sumita Pennathur started her tenure at the University of California, Santa Barbara (UCSB) in July 2007. Prior to UCSB, she held postdoctoral positions at both University of Twente in the Netherlands and Sandia National Laboratories in Livermore CA. She received her PhD in Mechanical Engineering at Stanford University in March 2006, where her research investigated electrokinetic transport of fluids at the nanoscale. Prior to Stanford, she received both her B.S. and M.S. in Aerospace and Aeronautical Engineering from M.I.T. where she studied microscale cavitation in MEMS devices. In addition to co-authoring an undergraduate textbook about Nanotechnology, she is the recipient of both the 2008 DARPA Young Faculty Award and the 2009 UC Junior Regents Faculty Award.
Jesse Adams received a bachelor's degree in mechanical engineering with a business minor from the University of Nevada, Reno. He graduated Summa Cum Laude and also received the outstanding mechanical engineering senior award. After winning a NSF graduate fellowship, Jesse went to Stanford University, where he received a Masters of Science in mechatronics. His research interests led him to pursue a Ph.D. in nanotechnology working with the co-inventor of the Atomic Force Microscope, Calvin Quate. He developed a high-speed multi-probe AFM, which necessitated extensive work in the Stanford clean room to fabricate active AFM probes. This research was enhanced by a learning technology and educational reform component under the direction of Larry Leifer, then Director of the Stanford Learning Laboratory. While at Stanford, Jesse served on a special committee for the provost, then Condoleezza Rice, to explore and recommend emergency graduate housing solutions. Jesse also served two terms as the assistant director of the respected sophomore college at Stanford.
While an assistant professor at the University of Nevada, Reno, Jesse did research on a self-sensing microcantilever platform being investigated for explosives detection, chemical vapor detection, and water quality sensing. In addition to this research, Jesse developed a new course in nanotechnology that trained students in a broad understanding of the field. Jesse is a co-author of a first-of-its-kind textbook, Nanotechnology: Understanding Small Systems, as well as 25 technical papers. He has multiple patents and patents pending, has given invited talks on scanning probe microscopy and microcantilever chemical sensing and won a regional and a national speaking award, as well as a national design award, a university innovation award, and the 2004 Scientific American 50 award in the defense category.
