Thandavarayan Maiyalagan – författare

Nanomaterials for Electrocatalysis provides an overview of the different types of nanomaterials, design principles and synthesis protocols used for electrocatalytic reactions. The book is divided into four parts that thoroughly describe basic principles and fundamental of electrocatalysis, different types of nanomaterials used, and their electrocatalytic applications, limitations and future perspectives. As electrochemical systems containing nanomaterials, with relevance to experimental situation, yield better results, this book highlights new information and findings. Provides an overview of nanomaterials applications for electrocatalytic processes, such as oxygen reduction reaction (ORR), oxygen evolution reaction (OER), hydrogen evolution reaction (HER) and CO2 reduction reaction (CO2RR) Provides information on the design and development of various nanomaterials appropriate for electrocatalytic applications Assesses the challenges of manufacturing nanomaterials at an industrial scale for electronic applications

Lithium-ion batteries are the most promising among the secondary battery technologies, for providing high energy and high power required for hybrid electric vehicles (HEV) and electric vehicles (EV). Lithium-ion batteries consist of conventional graphite or lithium titanate as anode and lithium transition metal-oxides as cathode. A lithium salt dissolved in an aprotic solvent such as ethylene carbonate and diethylene carbonate is used as electrolyte. This rechargeable battery operates based on the principle of electrochemical lithium insertion/re-insertion or intercalation/de-intercalation during charging/discharging of the battery. It is essential that both electrodes have layered structure which should accept and release the lithium-ion. In advanced lithium-ion battery technologies, other than layered anodes are also considered. High cell voltage, high capacity as well as energy density, high Columbic efficiency, long cycle life, and convenient to fabricate any size or shape of the battery, are the vital features of this battery technology. Lithium-ion batteries are already being used widely in most of the consumer electronics such as mobile phones, laptops, PDAs etc. and are in early stages of application in HEV and EV, which will have far and wide implications and benefits to society. The book contains ten chapters, each focusing on a specific topic pertaining to the application of lithium-ion batteries in Electric Vehicles. Basic principles, electrode materials, electrolytes, high voltage cathodes, recycling spent Li-ion batteries and battery charge controller are addressed. This book is unique among the countable books focusing on the lithium-ion battery technologies for vehicular applications. It provides fundamentals and practical knowledge on the lithium-ion battery for vehicular application. Students, scholars, academicians, and battery and automobile industries will find this volume useful.

Electrochemistry and Photo-Electrochemistry of Nanomaterials: Fundamentals and Applications explores how nanotechnology and nanomaterials can be utilized in the field of electrochemistry and photo-electrochemistry. The book covers the fundamentals of nanoscale electrochemistry and photo-electrochemistry for nanoscale materials systems, including multilayer nanofilms, nanowires, nanotubes, nanoparticles embedded in metal matrixes, and membranes containing nanoparticles. The creation of new materials for energy and sensing technologies that rely on understanding and control of chemical processes is also emphasized. Advances in characterization, synthesis, and fabrication of nanoscale materials and technologies are also discussed regarding the design of new materials.This book is suitable for academics and industry professionals working in the subject areas of materials science, materials chemistry, inorganic chemistry, and energy.

Reviews fundamental concepts of electrochemistry and photo-electrochemistry for nanoscale materials systemsIncludes the electrochemical techniques to synthesize, characterize, and control and improve the properties of nanoscale material systemsDiscusses the latest research directions to design new materials for energy and sensing applications

Biomass-Derived Carbon Materials for Energy Storage and Conversion Applications delves into this burgeoning field and addresses the pressing need for sustainable and cost-effective carbon sources. Highlighting biomass's unique advantages of cost-effectiveness, sustainability, and adjustable properties, it explores the various applications of carbon nanomaterials in energy storage and conversion. Divided into four parts, the book comprehensively examines biomass availability, synthetic protocols, structural engineering techniques, and characterization methods, offering insights into the design principles and applicability of these materials for supercapacitors, batteries, and electrocatalytic reactions. It serves as a useful reference for researchers, professionals, and academicians, and graduate/postgraduate students in the field.Provides academic and industrial perspectives on cutting-edge topics like surface functionalization, hybridization, and integration into energy devices, emphasizing sustainability and scalability.Examines the potential for biomass-derived carbon materials to enhance energy efficiency and reliability.Discusses economic and environmental implications, including life cycle assessment (LCA), carbon neutrality, and circular economy principles, aligning material development with global sustainability goals.