The term 'nanobattery' can refer not only to the nanosized battery, but also to the uses of nanotechnology in a macro-sized battery for enhancing its performance and lifetime. Nanobatteries can offer many advantages over the traditional battery, including higher power density, shorter charging time, and longer shelf life. Nano-generators refer to the uses of nanosized devices and materials to convert mechanical, thermal and light-based energies into electricity. Similar to with traditional battery, in nanobatteries, the chemical energy is converted into electricity. This book addresses the…mehr
The term 'nanobattery' can refer not only to the nanosized battery, but also to the uses of nanotechnology in a macro-sized battery for enhancing its performance and lifetime. Nanobatteries can offer many advantages over the traditional battery, including higher power density, shorter charging time, and longer shelf life. Nano-generators refer to the uses of nanosized devices and materials to convert mechanical, thermal and light-based energies into electricity. Similar to with traditional battery, in nanobatteries, the chemical energy is converted into electricity.
This book addresses the fundamental design concepts and promising applications of nanobatteries and nanogenerators. Particular application areas include healthcare, biomedical, smart nanodevices and nanosensors, which may require new electric power sources, including self-powered ability and nanostructured electric power sources. In this regard, nanobatteries and nanogenerators represent the next generation of electric power.
This is an important reference source for materials scientists, engineers and energy scientists, who are looking to increase their understanding of how nanotechnology is being used to create new energy storage and generation solutions.
Huaihe Song is a Professor at the State Key Laboratory of Chemical Resource Engineering, College of Materials and Engineering, Beijing University of Chemical Technology, China. He has 28 years of experience in the field of carbon materials research. His research area is in the preparation of advanced carbon materials and their applications, including pitch-based carbon materials (mesophase pitch and mesocarbon microbeads), carbon nanomaterials (carbon nanotubes, graphene, carbon-encapsulated metal nanomaterials, and onion-like carbons), carbon-based materials for energy storage (lithium-ion batteries and supercapacitors), and mesoporous carbons (ordered mesoporous carbons and carbon aerogels).
Inhaltsangabe
PART 1: BASIC PRINCIPLES 1. Nanobattery and Nanogenerator: An introduction 2. Methods for design and fabrication of nanobattery 3. Methods for characterization and evaluation of nanobattery 4. Nanoscale interface techniques for standardized integration of nanobattery 5. Mathematical modeling for charging and discharging processes of nanobattery 6. Methods for design and fabrication of nanogenerator 7. Methods for characterization and evaluation of nanogenerator 8. Nanoscale interface techniques for standardized integration of nanogenerator
PART 2: NANOMATERIALS FOR RECHARGEABLE BATTERY 9. Nanostructured anodes in rechargeable batteries 10. Nanostructured cathodes in rechargeable batteries 11.Nanomaterials for electrolyte materials in rechargeable batteries 12. Nanostructured membranes for battery separators (polymer electrolyte nano-membranes) 13. Nanomaterials and nanotechnology for high-performance rechargeable battery
PART 3: NANOMATERIALS FOR PRIMARY BATTERY 14. Nanomaterials and nanotechnology for high-performance primary battery 15. Regulatory, toxicological and environmentally issues of nanobattery 16. Nanobattery waste management
PART 4: APPICATION OF NANOBATTERY 17. Nanodiagnostics using nanobatteries 18. Medical nano-tools 19. Nano-robots 20. Smart textiles 21. Nanosensors for smart cities 22. High performance electric vehicles
PART 5: APPICATIONS OF NANOGENERATOR 23. Corrosion protection of metals at the nanoscale (cathodic protection) 24. Self-powered nanosensors using nanogenerators 25. Nanogenerators in wearable sensors 26. Smart textiles (Wearable Devices) 27. Implanted devices (to regulate the heart rate .) 28. Organ-on-a-chip (heart-on-chip)
PART 1: BASIC PRINCIPLES 1. Nanobattery and Nanogenerator: An introduction 2. Methods for design and fabrication of nanobattery 3. Methods for characterization and evaluation of nanobattery 4. Nanoscale interface techniques for standardized integration of nanobattery 5. Mathematical modeling for charging and discharging processes of nanobattery 6. Methods for design and fabrication of nanogenerator 7. Methods for characterization and evaluation of nanogenerator 8. Nanoscale interface techniques for standardized integration of nanogenerator
PART 2: NANOMATERIALS FOR RECHARGEABLE BATTERY 9. Nanostructured anodes in rechargeable batteries 10. Nanostructured cathodes in rechargeable batteries 11.Nanomaterials for electrolyte materials in rechargeable batteries 12. Nanostructured membranes for battery separators (polymer electrolyte nano-membranes) 13. Nanomaterials and nanotechnology for high-performance rechargeable battery
PART 3: NANOMATERIALS FOR PRIMARY BATTERY 14. Nanomaterials and nanotechnology for high-performance primary battery 15. Regulatory, toxicological and environmentally issues of nanobattery 16. Nanobattery waste management
PART 4: APPICATION OF NANOBATTERY 17. Nanodiagnostics using nanobatteries 18. Medical nano-tools 19. Nano-robots 20. Smart textiles 21. Nanosensors for smart cities 22. High performance electric vehicles
PART 5: APPICATIONS OF NANOGENERATOR 23. Corrosion protection of metals at the nanoscale (cathodic protection) 24. Self-powered nanosensors using nanogenerators 25. Nanogenerators in wearable sensors 26. Smart textiles (Wearable Devices) 27. Implanted devices (to regulate the heart rate .) 28. Organ-on-a-chip (heart-on-chip)