Most of us have been exposed to graphene through the use of pencils since elementary school. After all, pencil leads are made out of graphite, which are graphene layers that are piled on top of each other. Graphene is an excellent material and has stimulated much research interest due to its unique structure and interesting properties. There are several unique and powerful properties exhibited by graphene that makes it suitable for various advanced applications. For example, it is the thinnest material, with a thickness of only one atomic layer. It is also very strong, flexible, has high thermal and electrical conductivity and much more. In addition, it also has special electrical conductor and insulator properties with tunable optical properties. This book covers fundamental and advanced topics related to graphene, including the introduction and history, structure and chemistry, basic properties, and the preparation methods of graphene. Furthermore, graphene nanocomposites, different characterization techniques, as well as the basic and advanced graphene applications are presented within this book in order to provide a broad reference for researchers, scientists, as well as postgraduate and undergraduate students. Additionally, this book contains a special topic related to bio-based graphene which is currently gaining a lot of attention.

Graphene Bioelectronics covers the expending field of graphene biomaterials, a wide span of biotechnological breakthroughs, opportunities, possibilities and challenges. It is the first book that focuses entirely on graphene bioelectronics, covering the miniaturization of bioelectrode materials, bioelectrode interfaces, high-throughput biosensing platforms, and systemic approaches for the development of electrochemical biosensors and bioelectronics for biomedical and energy applications. The book also showcases key applications, including advanced security, forensics and environmental monitoring. Thus, the evolution of these scientific areas demands innovations in crosscutting disciplines, starting from fabrication to application. This book is an important reference resource for researchers and technologists in graphene bioelectronics—particularly those working in the area of harvest energy biotechnology—employing state-of-the-art bioelectrode materials techniques. - Offers a comprehensive overview of state-of-art research on graphene bioelectronics and their potential applications - Provides innovative fabrication strategies and utilization methodologies, which are frequently adopted in the graphene bioelectronics community - Shows how graphene can be used to make more effective energy harvesting devices

"Materials science influences all aspects of society, including the current challenges of environmental issues and of sustainable energy. It also impacts our daily life, because it studies common materials like nanomaterials, composites, hybrid materials, glass, and plastic. Materials science tries to improve these materials in ways such as adding scratch resistance to glass. This science also commonly studies composite materials. This book was motivated by the desire to broaden knowledge and use this knowledge to develop new materials for the utility of mankind. There are innumerable tools currently available that focus on specific knowledge that can largely serve the scientific community. However, this book also explores social issues and outlines applications of different materials. Additionally, this book presents research-based practices related to the usage of advanced materials and covers the application of nanomaterials in solar energy and medicine. The didactic approach of this book is perfectly suited to science and engineering students, as well as to biologists, physicists, or chemists who are not specialized in materials but who, nevertheless, wish to learn about this discipline. This work will also be appreciated by specialists in a particular aspect of materials science wishing to have a global view on the subject and to position their activity in a wider context"--

The Stone Age, the Bronze Age, the Iron Age... Every global epoch in the history of the mankind is characterized by materials used in it. In 2004 a new era in material science was opened: the era of graphene or, more generally, of two-dimensional materials. Graphene is the strongest and the most stretchable known material, it has the record thermal conductivity and the very high mobility of charge carriers. It demonstrates many interesting fundamental physical effects and promises a lot of applications, among which are conductive ink, terahertz transistors, ultrafast photodetectors and bendable touch screens. In 2010 Andre Geim and Konstantin Novoselov were awarded the Nobel Prize in Physics for groundbreaking experiments regarding the two-dimensional material graphene. The two volumes Physics and Applications of Graphene - Experiments and Physics and Applications of Graphene - Theory contain a collection of research articles reporting on different aspects of experimental and theoretical studies of this new material.

This book comprehensively reviews the key topics in microbial fuel cells (MFC) and its applications in areas related to energy and environmental mitigation. It covers the microbial electrochemistry and the generation of electricity from waste, various synthesis and characterization approaches of polymer-based MFC electrodes, the multifunctional properties of a MFC which allows its simultaneous use as a fuel cell, bioremediation and biosensor device. It provides new direction to the readers to better understand the chemistry in MFC and methods to improve their desired properties. This book is a very valuable reference source for graduates and postgraduates, engineers and research scholars in the areas related to fuel cells electrochemistry and pollution mitigation.

What if you discovered an infinitesimally thin material capable of conducting electricity, able to suspend millions of times its own weight, and yet porous enough to filter the murkiest water? And what if this incredible substance is created from the same element that fills the common pencil? That's graphene--a flat, two-dimensional, carbon-based molecule with a single sheet measuring only one atom thick. In this layperson's introduction to this revolutionary substance, a physicist and a chemist explain how graphene was developed, discuss the problems in scaling up production for large-scale commercial use, and forecast the potentially transformative effects of incorporating graphene into everyday life. Recent research developments include adding graphene to Silly Putty to make extremely sensitive and malleable medical sensors and compressing and fusing flakes of graphene to create a three-dimensional material that's ten times stronger than steel. This widely adaptable substance promises to change the way we interact with smartphones, laptops, information storage, and even condoms. It may also enable significant improvements to air purification, water filtration technologies, and drug delivery. This entertaining and widely accessible book offers a fascinating look into one of the most exciting developments in materials science in recent decades.

Graphene Extraction from Waste: A Sustainable Synthesis Approach for Graphene and its Derivatives introduces readers to strategies of graphene extraction from waste, an important advance in graphene material development to support the low-cost and large-scale production of this valuable material. The book compares the various green synthesis routes for graphene materials and its derivatives, with a view on environmental consequences, cost-effectiveness, scalability, possible health hazards and toxicity. Other sections discuss different categories of waste, such as plastic waste, agricultural waste and household waste and the specific considerations of deriving graphene from these sources.Throughout the book, attention is paid to the potential applications of graphene-derived from waste, including challenges and emerging strategies. The book is suitable for researchers and practitioners in research and development in industry who work in the disciplines of materials science and engineering, green chemistry and sustainability. - Reviews the latest advances in sustainable approaches for the extraction of graphene from common sources of waste - Discusses waste management strategies for plastics, household waste, agricultural waste, and their treatment for graphene extraction - Provides the most relevant green synthesis methods for graphene and its derivatives, considering cost, scalability and environmental and health impact