Ya Yang

Hybridized and Coupled Nanogenerators


Скачать книгу

      14  Index

      15  End User License Agreement

      List of Illustrations

      1 Chapter 1Figure 1.1 Hybrid energy cell for scavenging solar and mechanical energies. ...Figure 1.2 Electromagnetic–triboelectric hybridized nanogenerator for scaven...Figure 1.3 Electromagnetic–triboelectric hybridized nanogenerator for scaven...Figure 1.4 Hybridized nanogenerator for scavenging solar and wind energies. ...Figure 1.5 Large‐scale triboelectric nanogenerators (TENGs) for scavenging w...Figure 1.6 Large‐scale triboelectric nanogenerators (TENGs) for scavenging w...Figure 1.7 Working principle of pyroelectric and photovoltaic coupled nanoge...Figure 1.8 Illustration of multi‐effects coupled nanogenerator toward multi‐...Figure 1.9 One‐structure‐based multi‐effects coupled nanogenerator. (a) Sche...

      2 Chapter 2Figure 2.1 Main types of conventional wind turbines. (a) Horizontal axis win...Figure 2.2 Diagram of the plate‐based TENG. (a) Schematic diagram of the TEN...Figure 2.3 Sketches illustrating the electricity generation process (a–f) in...Figure 2.4 Diagram of the enhanced plate‐based TEG. (a) Schematic diagram of...Figure 2.5 Diagram of the elasto‐aerodynamics‐driven TENG. (a) Schematic dia...Figure 2.6 The CNCs/ITO film. (a) The schematic for preparing the CNCs/ITO f...Figure 2.7 Superhydrophobic surfaces on the Al substrates. (a) SEM image of ...Figure 2.8 Ag nanoparticles and Ag nanowires. (a) SEM image of the Ag nanowi...Figure 2.9 Schematic illustrations and simulation of the vibration. (a) The ...Figure 2.10 Simulation of the vibration film. (a–c) The displacement distrib...Figure 2.11 Output performance of the TENG. (a) Output voltage signals. (b) ...Figure 2.12 Rectified output performance of the TENG. (a) Short‐circuit curr...Figure 2.13 Output performance of the TENG. (a) The output voltage and the c...Figure 2.14 The working principle and a photograph of the fabricated self‐po...Figure 2.15 The self‐powered wind vector sensor system. (a) Photograph of th...Figure 2.16 The polarization system. (a) Schematic illustration of the worki...Figure 2.17 Wind‐driven wearable electronics. (a) TENG‐based shoe for monito...Figure 2.18 The self‐powered healthcare monitoring system. (a) Output voltag...Figure 2.19 The wind‐driven electronics light‐emitting diodes. (a) Photograp...Figure 2.20 Photograph of lighting equipment power by the TEGs. (a) Ten spot...Figure 2.21 The wind‐driven wireless sensor. (a) Schematic diagram of an int...Figure 2.22 The wind‐driven self‐powered wireless smart temperature sensor. ...Figure 2.23 The wind‐driven self‐charging Li‐ion battery. (a) Charging and d...Figure 2.24 The wind‐driven self‐powered pressure sensor. (a) Schematic diag...Figure 2.25 The comparison between conventional wind harvester and new wind ...

      3 Chapter 3Figure 3.1 Theoretical comparison of EMG and TENG. (a) Schematic fundamental...Figure 3.2 The shared‐electrode‐based hybridized nanogenerator. (a) Schemati...Figure 3.3 The rotating‐disk‐based hybridized nanogenerator. (a) Schematic d...Figure 3.4 Schematic diagram of the working principle of hybridized EMG–ENG....Figure 3.5 The spring‐based hybridized nanogenerator. (a) Schematic diagram ...Figure 3.6 The stretchable hybridized nanogenerator. (a) Schematic diagram o...Figure 3.7 The hybridized nanogenerator. (a) Schematic diagram of the fabric...Figure 3.8 The hybridized nanogenerator based on vibrating plate‐based struc...Figure 3.9 The hybridized nanogenerator based on elasto‐aerodynamics‐driven ...Figure 3.10 The hybridized nanogenerator based on fully enclosed structure. ...Figure 3.11 The hybridized nanogenerator based on the sliding structure. (a)...Figure 3.12 The glass fibers/silver nanowires. (a) Photograph of a conductiv...Figure 3.13 The PVB nanowire/PDMS composite film. (a) SEM image of the PVB n...Figure 3.14 The rough structures on the surfaces. (a) SEM image of the prepa...Figure 3.15 Output performance of the conductive fabric‐based stretchable hy...Figure 3.16 Output performance of the hybridized generator. (a) Voltage of t...Figure 3.17 Output performance of the linear‐grating hybridized generator vi...Figure 3.18 Output performance of the rotating‐disk‐based hybridized generat...Figure 3.19 Output performance of the hybridized generator. (a) The output v...Figure 3.20 Output performance of spring‐based EMG–TENG. (a) The output curr...Figure 3.21 Powering electronic devices via the hybridized nanogenerator. (a...Figure 3.22 Self‐powered wearable electronic watch. (a) Photograph of the fa...Figure 3.23 Self‐powered wearable devices. (a) Photograph of the fabricated ...Figure 3.24 Powering a white globe lamp via the hybridized nanogenerator. (a...Figure 3.25 Charging a self‐made Li‐ion battery via the hybridized nanogener...

      4 Chapter 4Figure 4.1 The images of different morphologic ZnO nanostructures. (a,b) SEM...Figure 4.2 Schematic diagrams of ZnO‐based devices. (a) The piezopotential d...Figure 4.3 The performances of the ZnO‐based devices. (a,c) IV curves of th...Figure 4.4 The SEM and TEM images of the devices based on electrochemical de...Figure