Hybridized and coupled nanogenerators have received increasing attention due to their potential applications in multi-energy scavenging and sensor fields. This comprehensive reviews on them giving a good tool for related academics and professionals.
Hybridized and coupled nanogenerators have received increasing attention due to their potential applications in multi-energy scavenging and sensor fields. This comprehensive reviews on them giving a good tool for related academics and professionals.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
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Autorenporträt
Ya Yang is currently Research Scientist at Beijing Institute of Nanoenergy and Nanosystems, Chinese Academy of Sciences, China. After his PhD from University of Science and Technology Beijing, China, he worked as a postdoctoral researcher in Georgia Institute of Technology, USA. His research interests include the hybridized nanogenerators, self-powered sensors, solar cells, and Li-ion batteries. He has published more than 120 Journal articles and holds 30 patents.
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
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
