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Graphene for Defense and Security by Andre U. Sokolnikov

Published online by Cambridge University Press:  10 July 2018

Abstract

Type
Book Reviews
Copyright
Copyright © Materials Research Society 2018 

This book is focused on the physics of an interesting material, graphene, with its unique two-dimensional crystal structure that confers special electrical, thermal, optical, and mechanical properties with a wide pallete of possible applications. It contains nine chapters, out of which the first two familiarize the reader with some specific phenomena, such as the Landau level effect and the quantum Hall effect, particularly interesting for graphene developments. The next three chapters deal with the physical properties and quantum mechanics of graphene, while chapters 6–8 report on sources and methods for producing graphene and characterization techniques for graphene-based materials. The last 50 pages of the final chapter are devoted to applications.

The book develops the basic concepts for understanding the versatility of graphene related to its electronic band structure, which may be engineered by various methods able to break graphene’s lattice symmetry, such as defect generation, water adsorption, and interaction with gases. In this context, some of graphene’s special properties are explained in detail. Micrometer-sized samples of graphene show some of the best electron mobility values ever measured. As the optical response of graphene nanoribbons may extend into the THz range by using an applied magnetic field, a practical application may be a graphene-based Bragg grating, which is a one-dimensional photonic crystal that is capable of excitation of surface electromagnetic waves in a periodic structure. Such phenomena may contribute to different devices and their improvements: fiber lasers, mode-locking, microwave saturable absorbers, polarizers, modulators in the microwave range, and broadband wireless access networks.

The plasmonic dynamics may exploit optical properties of graphene to design a solid-state laser in the THz range with high efficiency at room temperature. Thermal properties of graphene are also different from those of other carbon materials, such as graphite, nanotubes, or diamond, and the nature of conductivity at the charge-neutrality point has been discussed in connection with graphene-based device fabrication. Moreover, graphene is one of the strongest materials from a mechanical point of view. For instance, graphene exhibits more than 100 times greater breaking strength than steel. The ease of shaping and the firmness of thin graphene layers may facilitate making lighter vehicles and airplanes that use less fuel and generate less pollution. It is expected that graphene could replace silicon technology in many applications by 2020.

The title is a little misleading, as the book is not specific to graphene’s applications in defense and security, but it covers applications tangential to these areas, such as those mainly used in electronic devices: a new generation of high-frequency transistors, ultrafast photodetectors, optical modulators, memory devices, energy generation, and energy storage.

In order to take advantage of the information provided in this book, one needs a deep knowledge of quantum physics in solid materials and related phenomena. This monograph based on up-to-date references may be useful for PhD students and specialists in physical engineering and applied electronics.

Reviewer: Aurelia Meghea is an Emeritus Professor at the University Politehnica of Bucharest, Romania.

Footnotes

CRC Press, 2017 282 pages, $175.96 (e-book $197.96) ISBN 978-1-4987-2762-4

References

CRC Press, 2017 282 pages, $175.96 (e-book $197.96) ISBN 978-1-4987-2762-4