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Graphene: Preparations, Properties, Applications, and Prospects, Kazuyuki Takai, Seiya Tsujimura, Feiyu Kang, and Michio Inagaki Elsevier, 2019 620 pages, $193 (eBook $200) ISBN 9780128195765

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Graphene: Preparations, Properties, Applications, and Prospects, Kazuyuki Takai, Seiya Tsujimura, Feiyu Kang, and Michio Inagaki Elsevier, 2019 620 pages, $193 (eBook $200) ISBN 9780128195765

Published online by Cambridge University Press:  09 October 2020

K.S.V. Santhanam*
Affiliation:
School of Chemistry and Materials Science, Rochester Institute of Technology, USA.

Abstract

Type
Book Reviews
Copyright
Copyright © The Author(s), 2020, published on behalf of Materials Research Society by Cambridge University Press

This book is unique in that it discusses in a more detailed manner the graph-ene literature from the perspective of crystalline or defective layers. The focus is on graphene foams, films, horns, doping with foreign atoms, and electrical, thermal, chemical, mechanical, and biomedical aspects. The collective goal of the authors was to review the literature in an unprecedented way.

Chapter 1 provides an introduction to graphene, followed by a discussion on carbon materials, including highly oriented graphite materials, synthetic graphite materials, fibrous carbon materials, nanoporous carbon, spherical carbon materials, and glass-like carbon. The structure of graphite intercalation compounds is well covered.

Chapter 2 reviews the making of graphene by chemical vapor deposition (CVD), mechanical exfoliation, and chemical exfoliation. The materials produced by CVD using organic precursors have been compared with those arising from graphite exfoliation.

Chapter 3 discusses the electrical properties of graphene, carbon allotropes, carbon nanofibers, and graphite, with illustrations of graphene-based transistors, spintronics, sensor devices, and photon detectors. This chapter also presents the concept of “zero gap” semiconductors, Bernal stacking, pi electron band structures, spin injection efficiency, and the performance of graphene sensors in doped and undoped states.

The chemical properties of graphene-based materials relevant for a variety of applications is the basis of chapter 4. This chapter also includes discussions on energy- storage aspects and environment remediation relevant to batteries and capacitors. Chapter 5 elaborates on the mechanical properties of graphene, with illustrations of nanolubricants and mechanical sensors. The thermal properties of graphene, thermal interface materials, nanofluids, and thermal energy storage are reviewed in chapter 6. Chapter 7 includes discussions on biomedical properties, biocompatibility, cell management, drug delivery aspects, and biosensors. This chapter compares the performance of graphene with carbon nanotubes in their biocompatibility.

Chapter 8 is especially interesting, as it introduces materials derived from graph-ene (known as graphene derivatives) such as fluorographene, graphene oxide, graphyne, and also single-layer compounds such as boron nitride nanotubes and transition-metal sulfides. The concluding chapter 9 summarizes new knowledge added to materials science from the studies of graphene and future prospects.

This book is a solid contribution to materials science and engineering, as it reviews published research in the literature up until 2018. The book features an index for the easy selection of topics and is well illustrated. Graduate students could use the book for advanced research on graphene, and it serves as a good source on graphene developments viewed as a material derived from a CVD process, contrasting it with mechanical or chemical exfoliation. But it is not a textbook and does not include problems or worked examples.