Introduction to NanoscienceOUP Oxford, 2010 - 457 oldal Nanoscience is not physics, chemistry, engineering or biology. It is all of them, and it is time for a text that integrates the disciplines. This is such a text, aimed at advanced undergraduates and beginning graduate students in the sciences. The consequences of smallness and quantum behaviour are well known and described Richard Feynman's visionary essay 'There's Plenty of Room at the Bottom' (which is reproduced in this book). Another, critical, but thus far neglected, aspect of nanoscience is the complexity of nanostructures. Hundreds, thousands or hundreds of thousands of atoms make up systems that are complex enough to show what is fashionably called 'emergent behaviour'. Quite new phenomena arise from rare configurations of the system. Examples are the Kramer's theory of reactions (Chapter 3), the Marcus theory of electron transfer (Chapter 8), and enzyme catalysis, molecular motors, and fluctuations in gene expression and splicing, all covered in the final Chapter on Nanobiology. The book is divided into three parts. Part I (The Basics) is a self-contained introduction to quantum mechanics, statistical mechanics and chemical kinetics, calling on no more than basic college calculus. A conceptual approach and an array of examples and conceptual problems will allow even those without the mathematical tools to grasp much of what is important. Part II (The Tools) covers microscopy, single molecule manipulation and measurement, nanofabrication and self-assembly. Part III (Applications) covers electrons in nanostructures, molecular electronics, nano-materials and nanobiology. Each chapter starts with a survey of the required basics, but ends by making contact with current research literature. |
Tartalomjegyzék
1 What is Nanoscience? | 1 |
The Basics | 17 |
Tools | 133 |
Applications | 233 |
Units conversion factors physical quantities and useful math | 381 |
Theres plenty of room at the bottom | 384 |
Schrödinger equation for the hydrogen atom | 396 |
The damped harmonic oscillator | 400 |
The Gibbs distribution | 409 |
Quantum partition function for a single particle | 411 |
Partition function for N particles in an ideal gas | 413 |
Atomic units | 414 |
Hückel theory for benzene | 415 |
A glossary for nanobiology | 417 |
Solutions and hints for the problems | 424 |
| 447 | |
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Gyakori szavak és kifejezések
acid atoms band beam Boltzmann distribution bond calculated called cantilever carbon carbon nanotubes cell Chapter charge chemical complex components concentration conductance constant corresponding density dipole distance distribution electron transfer entropy equilibrium example Fermi Fermi energy fermions fluctuations fluorescence force free energy frequency gene given hydrogen hydrophobic illustrated in Fig interaction ions kinetic laser lattice layer magnetic material measured metal microscope molecular momentum nanoscale nanostructures optical orbitals oscillator oxidation pair particle partition function Phys potential probability amplitude probe problem protein proton quantum dots quantum mechanics quantum number reactants reaction reaction coordinate resistance resonance result sample scale scanning scanning tunneling microscopy Schrödinger equation semiconductor shown in Fig shows silicon single molecule solution spin structure surface temperature thermal thermodynamic tunneling wave vector wavefunction wavelength zero