Current and Future Developments in Nanomaterials and Carbon Nanotubes Series

Carbon is one of the most investigated material in the history of nanoscience and is mainly responsible for the current nanotechnology boom. The field of technology is very progressing at an exponential rate, with a wide variety of research articles and book chapters appearing in scholarly literature every year. Introduction to Carbon Nanomaterials presents information on new technologies based on the application of carbon nanotubes and the methods used to prepare carbon nanotubes are also discussed in detail. Key Features: - emphasizes the mechanisms used in developing and synthesizing carbon nanotubes. - explains the unique electrical, optical, mechanical, thermal and vibrational properties of carbon nanotubes with changes in these properties due to structural differences. - provides information about applications of enhanced carbon nanotube structures with bibliographic references - highlights the significance of carbon nanotubes in delivering a wide variety of molecular payloads including drugs, small organic molecules, oligonucleotides, proteins, siRNA, vaccines and nutrients. - explains the effects of carbon nanotubes on biological processes such as cell viability, proliferation, reactive oxygen species (ROS) producing ability, genotoxicity, extra cellular matrix remodelling/tissue remodeling, mutagenicity and toxicology. Introduction to Carbon Nanomaterials is a useful resource for novice nanotechnology researchers, undergraduates and post-graduate students who are interested to peruse a career in carbon nanomaterials research.

This reference reviews the reported literature on new approaches of nanocomposite material preparation and their applications in the development of physical, chemical, electrochemical, biological, fluorescence and colorimetric sensors. Sensor nanomaterials have been extensively used to amplify signals in the detection of a range of chemicals including toxic gases, biochemical nutrients, ions, explosives, pesticides and drugs to name a few. 14 chapter contributions highlight state-of-the-art sensors in recent years by outlining the synthesis, role and progress of nanocomposite materials in fabricating flexible and multifunctional sensing platforms in sensor technologies. Chapters first introduce the reader to nanocomposite materials and their role in making a wide array of sensors including metal-organic, graphene-based and polymeric sensors. The chapters then progress into applications of sensors for the detection of chemicals such as blood glucose, heavy metal and other toxic ions, hydrazine, humidity and explosive. Each chapter explains the required materials for electrodes and material components for a specific sensor platform with additional information about sample collection, threshold values and perspectives where appropriate. The book is intended as a compilation of knowledge for designing novel nanocomposite materials to be used as sensing platforms in sensor technologies. It serves as an informative resource for a broad range of readers including graduates and post-graduates, Ph. D. scholars, faculty members and professionals working in the area of material science, the healthcare industry, biological sciences, medical sciences, and environmental sciences.

This volume describes recent advancements in the synthesis and applications of nanomaterials for energy harvesting and storage, and optoelectronics technology for next-generation devices. This book consists of 15 chapters that cover a range of nanomaterials and the corresponding technologies. The initial chapters summarize the recent progress in applications of nanomaterials like carbon nanotubes, metal oxides, and graphene oxides-based hybrids in solar energy harvesting using recent photovoltaic technologies. These chapters are followed by reviews on nanowires, graphene quantum dots, boron nitrides, carbon nano onions and metal organic frameworks leading to the fabrication of supercapacitors, bio-sensors, lithium-ion batteries and hydrogen storage applications. The final set of chapters cover the next generation fuel cells using polymer nanocomposites, ferroelectric liquid crystal nanocomposite and optoelectronic nanomaterials for optical memory and displays devices. Key Features: Describes the types of nanomaterials that are fundamental to energy storage and electronic systems. These materials include nanowires, graphene quantum dots, boron nitrides, carbon nano onions and metal organic frameworks (MOFs), Covers the processes for nanomaterial synthesis Reviews important photovoltaics applications of nanomaterials, including their use in energy storage, batteries and optoelectronic devices Discusses the application of nanomaterials in electronics for sensing, bioelectronics, memory, nanocomposites for fuel cells, ferroelectric liquid crystal nanocomposites and optoelectronic nanomaterials for optical memory and displays Provides references for further reading in every chapter The volume informs engineers, academic researchers, research scholars and graduate students working in the area of nanomaterials for energy generation, storage and optoelectronics.

Synthesis and Applications of Semiconductor Nanostructures consists of 15 chapters that focus on synthesis, characterization and multifaceted potential applications of semiconductor nanostructures, metal organic frameworks (MOFs) and nanostructure impregnated metal-organic frameworks (MOFs). Special materials included in the volume include doped glasses, functionalized carbon nanotubes, doped graphene and graphene nanoribbons. The contributions highlight numerous bottom-up and top-down techniques for the synthesis of semiconductor nanostructures. Several industrial processes such as hydrogen production, wastewater treatment, carbon dioxide reduction, pollution control and oxidation of alcohols have been demonstrated in the context of semiconductor nanomaterial applications. The volume also has chapters dedicated to updates on the biomedical applications of these nanomaterials. This volume is a timely resource for postgraduate students, academicians, researchers and technocrats, who are involved in R&D activities with semiconductor nanomaterials and metal organic frameworks.