| Literature DB >> 26028354 |
Guan Wu1, Ying Hu1, Yang Liu1, Jingjing Zhao1, Xueli Chen1, Vincent Whoehling2, Cédric Plesse2, Giao T M Nguyen2, Frédéric Vidal2, Wei Chen1.
Abstract
Ionic actuators have attracted attention due to their remarkably large strain under low-voltage stimulation. Because actuation performance is mainly domiEntities:
Year: 2015 PMID: 26028354 PMCID: PMC4458862 DOI: 10.1038/ncomms8258
Source DB: PubMed Journal: Nat Commun ISSN: 2041-1723 Impact factor: 14.919
Figure 1Fabrication of the porous graphic carbon nitride electrode.
(a) Illustration of the preparation of the g-CN materials. (b) TEM images of g-CN800 °C, scale bar 100 nm. (c) SEM images of g-CN800 °C, scale bar 1μm. (d) The pore size distribution of g-CN800 °C and RGO and their contribution to SSA. (e) XRD patterns of g-CN550 °C and g-CN800 °C.
Figure 2Construction of the graphic carbon nitride electrode-based electrochemical actuator.
(a) Preparation of the g-CN800 °C actuator. SEM images of the surface, scale bar 2 μm (b) and cross section, scale bar 30 μm (c) of the g-CN800 °C actuator. (d) TEM image of PEO-NBR, scale bar 500 nm.
Figure 3Charge storage behaviour of the electrochemical actuators.
(a) Cyclic voltammetry (CV) curves for the g-CN800 °C and RGO electrode-based actuators at 10 mV s−1 sweep rate. (b) The calculated capacitances of devices at different scan rates.
Figure 4Bending performance of low-voltage-driven electrochemical actuators.
(a) Bending response of actuators based on g-CN800 °C and RGO electrodes at an applied square wave voltage of ±3 V with a frequency of 0.1 Hz. (b) Time-dependent displacement of g-CN800 °C and RGO actuators under 3 V.
Figure 5Nitrogen active site analysis.
(a) The calculated capacitances (scan rate 10 mV s−1), peak to peak bending displacement (0.1 Hz) and N contents of the g-CN electrodes. (b) The contribution of different N active sites and the electric conductivity of the actuators.
Figure 6Schematic illustration of the actuation mechanism.
(a) Bending motion of the g-CN actuator. (b) Schematic illustration of the pore structure and cation-induced mechanical output of the g-CN actuator.