Biomass-Based Supercapacitors (eBook)

BIOMASS-BASED SUPERCAPACITORS

Authoritative resource addressing the fundamentals, design, manufacturing, and industrial applications of supercapacitors based on biomass

Biomass-Based Supercapacitors presents a systematic overview and recent developments in the research, design, and fabrication of supercapacitors using biomass, discussing fundamentals, advancements, industrial applications, and the manufacturing process of biomass-derived supercapacitors. The text also considers environmental and economic aspects of the technology, along with biomass-based supercapacitors in the context of circular economy.

Written by a team of international experts in the field of supercapacitors, Biomass-Based Supercapacitors covers sample topics such as:

• Basic foundational knowledge surrounding supercapacitors, electrochemical techniques for supercapacitors, and different types of supercapacitors
• Biomass derived electrode materials for supercapacitors, such as activated and non-activated carbon, carbon from pretreated biomass, carbonate salts-activated carbon, and more
• Electrolytes, separators, and packaging materials for supercapacitors using biomass and binding materials from biomass for supercapacitors
• Future outlooks and challenges for the development of biomass-based supercapacitors, from the lab to practical applications in industry

Biomass-Based Supercapacitors is an excellent resource for academic researchers and industrial scientists working in the areas of supercapacitor fabrication, energy materials and energy storage devices, electrochemistry, materials science, biomass conversion, green chemistry, and sustainability.

Dr. Md. Abdul Aziz is a Research Scientist-II at Interdisciplinary Research Center for Hydrogen and Energy Storage, King Fahd University of Petroleum & Minerals, Saudi Arabia. His main research interests are preparation, immobilization, and functionalization of nanomaterials and carbonaceous materials, and their application in supercapacitors, water splitting, chemical and biochemical sensors.

Dr. Syed Shaheen Shah is a JSPS Post-Doctoral Fellow in the Department of Material Chemistry, Graduate School of Engineering, Kyoto University, Japan. His research interests focus on the development and mechanistic investigation of advanced nanomaterials for energy harvesting and storage applications, such as supercapacitors, electrochemical water splitting, and electrochemical sensors.

---

BIOMASS-BASED SUPERCAPACITORS Authoritative resource addressing the fundamentals, design, manufacturing, and industrial applications of supercapacitors based on biomass Biomass-Based Supercapacitors presents a systematic overview and recent developments in the research, design, and fabrication of supercapacitors using biomass, discussing fundamentals, advancements, industrial applications, and the manufacturing process of biomass-derived supercapacitors. The text also considers environmental and economic aspects of the technology, along with biomass-based supercapacitors in the context of circular economy. Written by a team of international experts in the field of supercapacitors, Biomass-Based Supercapacitors covers sample topics such as: Basic foundational knowledge surrounding supercapacitors, electrochemical techniques for supercapacitors, and different types of supercapacitors Biomass derived electrode materials for supercapacitors, such as activated and non-activated carbon, carbon from pretreated biomass, carbonate salts-activated carbon, and more Electrolytes, separators, and packaging materials for supercapacitors using biomass and binding materials from biomass for supercapacitors Future outlooks and challenges for the development of biomass-based supercapacitors, from the lab to practical applications in industry Biomass-Based Supercapacitors is an excellent resource for academic researchers and industrial scientists working in the areas of supercapacitor fabrication, energy materials and energy storage devices, electrochemistry, materials science, biomass conversion, green chemistry, and sustainability.