Nano-Physics and Bio-Electronics ：A New Odyssey

Publication subTitle ：A New Odyssey

Author： Chakraborty T.;Peeters F.;Sivan U.

Publisher： Elsevier Science‎

Publication year： 2002

E-ISBN: 9780080537245

P-ISBN(Paperback): 9780444509932

P-ISBN(Hardback): 9780444509932

Subject： O413 quantum theory;TB3 Engineering Materials

Language： ENG

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Description

This book is a collection of some of the invited talks presented at the international meeting held at the Max Planck Institut fuer Physik Komplexer Systeme, Dresden, Germany during August 6-30, 2001, on the rapidly developing field of nanoscale science in science and bio-electronics Semiconductor physics has experienced unprecedented developments over the second half of the twentieth century. The exponential growth in microelectronic processing power and the size of dynamic memorie has been achieved by significant downscaling of the minimum feature size. Smaller feature sizes result in increased functional density, faster speed, and lower costs. In this process one is reaching the limits where quantum effects and fluctuations are beginning to play an important role. This book reflects the achievements of the present times and future directions of research on nanoscopic dimensions.

Chapter

Front Cover

pp.： 1 – 4

Nano-Physics & Bio-Electronics: A New Odyssey

pp.： 4 – 5

pp.： 5 – 8

Preface

pp.： 6 – 10

Contents

pp.： 8 – 6

Chapter 1. Electronic states and transport in carbon nanotubes

pp.： 10 – 74

Chapter 2. Vertical diatomic artificial quantum dot molecules

pp.： 74 – 94

Chapter 3. Optical spectroscopy of self-assembled quantum dots

pp.： 94 – 120

Chapter 4. Generation of single photons using semiconductor quantum dots

pp.： 120 – 156

Chapter 5. Spin, spin-orbit, and electron-electron interactions in mesoscopic systems

pp.： 156 – 196

Chapter 6. Kondo effect in quantum dots with an even number of electrons

pp.： 196 – 222

Chapter 7. From single dots to interacting arrays

pp.： 222 – 246

Chapter 8. Quantum dots in a strong magnetic field: Quasi-classical consideration

pp.： 246 – 266

Chapter 9. Micro-Hall-magnetometry

pp.： 266 – 290

Chapter 10. Stochastic optimization methods for biomolecular structure prediction

pp.： 290 – 312

Chapter 11. Electrical transport through a molecular nanojunction

pp.： 312 – 332

Chapter 12. Single metalloproteins at work: Towards a single-protein transistor

pp.： 332 – 350

Chapter 13. Towards synthetic evolution of nanostructures

pp.： 350 – 362

Subject index

pp.： 362 – 364

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