Abstract
Having grown rapidly during the last two decades, and successfully synthesized the achievements of physics, chemistry, life science as well as information and computational science and technology, nanoscience and nanotechnology have emerged as interdisciplinary fields of modern science and technology with various prospective applications towards environmental protection and the sustainable development of industry, agriculture, public health etc. At the present time, there exist many textbooks, monographs and encyclopedias on nanoscience and nanotechnology. They present to readers the whole process of development from the emergence of new scientific ideas to comprehensive studies of concrete subjects. They are useful for experienced scientists in nanoscience and nanotechnology as well as related scientific disciplines. However, there are very few textbooks on nanoscience and nanotechnology for beginners—senior undergraduate and junior graduate students. Published by Garland Science in August 2011, Introductory Nanoscience: Physical and Chemical Concepts by Masaru Kuno is one of these rare textbooks.
The purpose of this book is twofold. In a pedagogical manner the author presents the basic physical and chemical concepts of nanoscience and nanotechnology. Students with a background knowledge in general chemistry and semiclassical quantum physics can easily understand these concepts. On the other hand, by carefully studying the content of this textbook, readers can learn how to derive a large number of formulae and expressions which they will often use in their study as well as in their future research work. A distinguishing feature of the book is the inclusion of a large number of thought problems at the end of each chapter for demonstrating how to calculate the numerical values of almost all physical quantities involved in the theoretical and experimental studies of all subjects of nanoscience and nanotechnology. The author has successfully achieved both of the main aims of the textbook.
The book consists of 15 chapters. According to their detailed contents they can be divided into three groups. In five chapters forming the first group (Introduction, Structure, Length Scales, Types of Nanostructures, Absorption and Emission Basics) the author presents the notions, definitions and concepts related to nanosystems, as well as the length scales of all their physical parameters. The contents of these chapters have been written for all readers studying any undergraduate academic programme in natural sciences and engineering. The subsequent seven chapters forming the second group (A Quantum Mechanics Review, Model Quantum Mechanics Problems, Additional Model Problems, Density of States, Bands, Time-Dependent Perturbation Theory, Interband Transitions) contain a comprehensive and easily understandable presentation of the theoretical basics of nanoscience. The last three chapters (Synthesis, Characterization, Applications) contain presentations on the fundamental methods in the experimental studies and applications of nanosystems.
This book is very useful not only for training beginners in research and engineering in nanoscience and nanotechnology, but also for attracting the interest of specialists in other scientific disciplines to the application of the achievements of this new emerging multidisciplinary scientific field.