This is an excellent book on the physical properties of low-dimensional carbon and newer noncarbon materials. There are nine chapters covering the physical properties of low-dimensional materials employing elementary theories of solids. This book will be useful for researchers working on low-dimensional materials.

Chapter 1 provides an overview of theoretical approaches used to predict the properties of low-dimensional materials with example calculations. Brief overviews of molecular orbital theory and density functional theory are discussed with appropriate diagrams.

Chapter 2 presents the electronic properties of low-dimensional solids. Free-electron theory and the tight-binding model are employed in discussing the band and electronic structure of solids.

Chapter 3 deals with vibrational properties of low-dimensional materials. The basics of Raman spectroscopy and surface-enhanced Raman spectroscopy are discussed with illustrations and experimental data for graphite.

Chapter 4 discusses fabrication and characterization of single-walled and multiwalled carbon nanotubes. How the energy bandgap changes with size and how the frequencies of radial breathing modes changes with the nano tube diameter are well discussed.

Chapter 5 gives an overview of the physical properties of boron nitride nanotubes, boron, and silicon nanotubes. Raman spectra, infrared spectra, and high-resolution transmission electron microscopy images included are useful.

Graphene structures and their physical properties are presented in chapter 6. The anomalous quantum Hall effect in graphene structures is briefly discussed with the help of energy state diagrams. Identifying the number of layers using Raman spectra is discussed beautifully.

Chapter 7 presents an overview of other low-dimensional materials, such as boron nitride, MoS2, NbSe2, and selenium. The highest occupied molecular orbital and lowest occupied molecular orbital energy-level dependency on the wave vector in all of these structures are depicted well.

Chapter 8 discusses magnetism in low-dimensional materials. The basics of magnetism and experimental techniques to probe the magnetic moments are well discussed with appropriate data and figures.

Superconductivity in low-dimensional materials is discussed in the last chapter. Thickness-dependent transition temperatures in Pb films, selenide, and FeSe superconductors are briefly discussed, along with their structures and experimental resistance data. Superconductivity in graphene and single-walled carbon nanotubes is also briefly discussed.

This is an outstanding book covering the preparation and physical properties of low-dimensional materials. The references in each chapter are up to date. The author did not intend the book as a textbook for undergraduate or graduate students; therefore, there are no problems included in any of the chapters. Nonetheless, I strongly recommend this book to all researchers interested in low-dimensional materials.