Buch, Englisch, 366 Seiten, Format (B × H): 175 mm x 249 mm, Gewicht: 885 g
Design, Performance, and Applications
Buch, Englisch, 366 Seiten, Format (B × H): 175 mm x 249 mm, Gewicht: 885 g
ISBN: 978-3-527-34634-9
Verlag: WILEY-VCH
A comprehensive guide to efficiently scavenge multi-energies from the surrounding environment to power some electronic devices and realize self-powered sensing!
With the advantages of high-integration level, low cost, and high-conversion efficiency, hybridized nanogenerators have many potential applications in multi-energy scavenging and sensor fields. This book offers a comprehensive review of the design, performance, and applications of hybridized and coupled nanogenerators. The author—a noted expert on the topic—explores the various new hybridized and multi-effects coupled nanogenerators.
The book examines the current approaches of improving electric generation performance and offers an introduction to the applications of hybridized nanogenerators in energy harvesting and sensing. This technology has proven to be highly applicable in multi-energy scavenging and self-powered sensor fields. This book includes:
- Examines the potential applications of hybridized and coupled nanogenerators in multi-energy scavenging and sensor fields
- Covers the principles of device design
- Explores the most current approaches to improve performance
- Reviews various multi-effects coupled nanogenerators and their potential applications
Written for materials scientists, engineering scientists, electronics engineers, bioengineers, sensor developers, and sensor industry professionals, This book is a guide to hybridized and coupled nanogenerators that achieve the maximum utilization of multi-type and stable energies.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
1 OVERVIEW
1.1 Introduction
1.2 Hybridized nanogenerators
1.3 Coupled nanogenerators
1.4 Applications
1.5 Conclusion and prospects
2 WIND-DRIVEN TRIBOELECTRIC NANOGENERATORS
2.1 Introduction
2.2 Conventional wind harvester
2.3 Triboelectric nanogenerators for scavenging wind energy
2.4 Comparison
2.5 Conclusion
3 ELECTROMAGNETIC-TRIBOELECTRIC HYBRIDIZED NANOGENERATORS
3.1 Introduction
3.2 Working mechanisms
3.3 Hybridized devices structure and working mechanisms
3.4 Materials
3.5 Performance
3.6 Applications
3.7. Summary and perspectives
4 OTHER HYBRIDIZED NANOGENERATORS
4.1 Introduction
4.2 Hybridized photoelectric and piezoelectric nanogenerator
4.3 Hybridized photoelectric and triboelectric nanogenerator
4.4 Hybridized photoelectric and pyroelectric nanogenerator
4.5 Conclusions and Prospects
5 HYBRIDIZING NANOGENERATORS AND SENSORS
5.1 Introduction
5.2 Materials
5.3 Design of self-powered sensors
5.4 Performance
5.5 Applications
5.6 Conclusion and Prospects
6 HYBRIDIZING NANOGENERATORS AND ENERGY STORAGE DEVICES
6.1 Introduction
6.2 Working Mechanisms
6.3 Materials
6.4 Devices Structure and Design
6.5 Performance
6.6 Applications
6.7 Conclusions and Prospects
7 PYROELECTRIC AND THERMOELECTRIC NANOGENERATORS
7.1 Introduction
7.2 Working Mechanisms
7.3 Progress of Pyroelectric Nanogenerators
7.4 Progress of Thermoelectric Nanogenerators
7.5 Conclusions and Prospects
8 PHOTOVOLTAIC-PYROELECTRIC COUPLED EFFECT NANOGENERATORS
8.1 Introduction
8.2 Basic Principle
8.3 Materials
8.4 Device Design
8.5 Performance
8.6 Applications
8.7 Conclusions and Prospects
9 MUTI-EFFECTS COUPLED NANOGENERATORS
9.1 Introduction
9.2 Materials
9.3 Device Design and Working Principle
9.4 Performance
9.5 Applications
9.6 Conclusions and Prospects
10 COUPLED NANOGENERATORS FOR NEW PHYSICAL EFFECTS
10.1 Introduction
10.2 Pyro-phototronic effect
10.3 Ferro-pyro-phototronic effect
10.4 Thermo-phototronic effect
10.5 Conclusions and Prospects
