Here, leading scientists report on why and how diamond can be optimized for applications in bioelectronic and electronics. They cover such topics as growth techniques, new and conventional doping mechanisms, superconductivity in diamond, and excitonic properties, while application aspects include quantum electronics at room temperature, biosensors as well as diamond nanocantilevers and SAWs. Written in a review style to make the topic accessible for a wider community of scientists working in interdisciplinary fields with backgrounds in physics, chemistry, biology and engineering, this is essential reading for everyone working in environments that involve conventional electronics, biotechnology, quantum computing, quantum cryptography, superconductivity and light emission from highly excited excitonic systems.

Satoshi Koizumi is Senior Researcher at the National Institute for Materials Science, Japan. As a member of the Super Diamond Group he is working on synthesis and characterization of diamond and cubic boron nitride (cBN), both high potential materials for electronic devices.

Christoph Nebel is Team Leader at the Diamond Research Center oft the National Institute of Advanced Industrial Science and Technology (AIST), Japan. His research work concentrates on characterization and development of nano-structured multi-array bio-sensors and field emission devices, both based on diamond. After owning positions at the Xerox Research Laboratories, Palo Alto/USA, and the Walter Schottky Insitute at the Technical University of Munich/Germany, he moved to Japan to continue his research on diamond.

Milos Nesladek is Professor at the University of Hasselt in Belgium and Senior Researcher at the Saclay Research Center of the Atomic Energy Commissariat (CEA), France. His main interests include PE CVD growth, optical characterisation and defect spectroscopy of diamond films and novel electronic materials.

Physics and Applications of CVD Diamond

Here, leading scientists report on why and how diamond can be optimized for applications in bioelectronic and electronics. They cover such topics as growth techniques, new and conventional doping mechanisms, superconductivity in diamond, and excitonic properties, while application aspects include quantum electronics at room temperature, biosensors as well as diamond nanocantilevers and SAWs.

Written in a review style to make the topic accessible for a wider community of scientists working in interdisciplinary fields with backgrounds in physics, chemistry, biology and engineering, this is essential reading for everyone working in environments that involve conventional electronics, biotechnology, quantum computing, quantum cryptography, superconductivity and light emission from highly excited excitonic systems.

Marshall Stoneham: Thinking about diamond

Olivier Williams, Milos Nesladek: Growth and properties of nanocrystalline diamond Films

Tokuyuki Teraji: Chemical Vapor Deposition of Homoepitaxial Diamond Films

Yutaka Anado, Atsuhito Sawabe: Heteroepitaxy of diamond

C. E. Nebel, B. Rezek, D. Shin, H. Watanabe: Surface electronic properties of H-terminated diamond in contact with electrolytes

Shin, B. Rezek, C.E. Nebel: Photo- and electrochemical bonding of DNA to single crystalline CVD diamond

Vincent Mortet, Ken Haenen, Oliver Williams: Diamond: Acoustic wave filters and sensors applications

Jonathan Goos: Defects and dopants in diamond

Satoshi Koizumi, Mariko Suzuki, Julien Pernot: n-Type doping of diamond: growth, electrical transport and devices

Jelezko, J. Wrachtrup: Single defect centers in diamond

Hideyo Okushi, Hideyuki Watanabe, Satoshi Yamasaki, Shokichi Kanno: Emission properties from dense exciton gases in diamond

Heinz Pernegger: High Mobility Diamonds and Particle Detectors

Etienne Bustarret: Superconducting diamond