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rel="nofollow" href="#ulink_8f4ed243-3cb9-53f4-97a7-8823e5901d43">Figure 2.14c showed the CV curves of the fabricated SCs after several healing cycles. The specific capacitance of the self‐healing device obtained from the CV curve was 61.4 mF cm−2 at a scan rate of 10 mV s−1. We can see even after four cutting–healing cycles, 71.8% of the capacitance retention was observed, providing an excellent self‐healing performance. This work may encourage the design and fabrication of the 1D fiber shaped self‐healable energy storage and wearable electronics.

      Self‐healable 2D planar SCs are another attractive energy storage because they possess the advantage of 2D devices like small size, low weight, ease of handing in appearance as well as the ultralong lifespan of the stretchable electronics. As a typical example, Huang et.al fabricated a 2D planar self‐healable SC based on PAA dual cross linked by hydrogen bonding and vinyl hybrid silica nanoparticles (VSNPs) [31]. Figure 2.14d illustrated the schematics of the fabrication process of the highly stretchable and self‐healable SCs. As for electrode materials, CNT papers were synthesized by CVD, and then deposited with the PPy, which were attached on the both side of the self‐healable VSNPs‐PAA gel electrolyte‐based film to prepare a self‐healable planar SCs. Figure 2.14e showed the demonstration of and ionic conductivity of the self‐healed substrate. The wound in the VSNPs‐PAA film could be autonomously repaired via the intermolecular hydrogen bonds among the cross‐linked polymer chains on the VSNPs in 10 mins under the ambient condition, which has no effect on the ionic conductivity and mechanical properties of the VSNPs‐PAA film. The CV curves with different cut‐healing times were depicted in the Figure 2.14f. The fabricated self‐healable SCs exhibited a specific capacitance of 61.4 mF cm−2 at a scan rate of 10 mV s−1, which was kept unchanged even after four healing cycles.

      2.3.3 Stretchable Integrated System

      Image described by caption. Image described by caption.

      Source: Reproduced with permission [28]. © 2015, American Chemical Society.

      (d) Schematics of fabrication strategies for highly stretchable and healable SCs. (e) Demonstration and ionic conductivity of the self‐healed substrate. (f) CV curves with different cut‐healing times.

      Source: Reproduced with permission [31]. © 2015, Nature Publishing Group.

      The integrated power pack comprising either wireless power transmission or internal power generator is highly desired for wearable electronics. Nanogenerator is one of the most popular power generators used in an integrated system, which could collect the energy produced by human activities [88–95]. Researches on nanogenerators was first reported in 2006 by Prof. Zhonglin Wang, and then a series of integrated systems with nanogenerator were designed [96–99]. For example, Guo et al. provided a stretchable all‐in‐one integrated system that contains triboelectric nanogenerator, SCs, and an electric watch, which could harvest all kinds of mechanical energy from human motions (bending, stretching) and transfer to SCs for powering the wearable watch [98]. Solar cells that convert sunlight into electricity are considered as the most promising energy conversion devices, which are also introduced to integrated system [42, 100]. Most recently, Yun et.al reported on the fabrication of stretchable integrated system including solar cells, all‐solid‐state MSC, and a strain sensor [101]. In this integrated system, the PPy@CNT electrode based MSC arrays were connected on the PI substrate, resembling a serpent in form. The graphene foam base strain sensor was directly prepared on the deformable PDMS substrate. MSC array and solar cells were separately embedded onto the PDMS substrate. When the MSC array was placed into the deformable Ecoflex substrate, the PI film was removed. The obtained integrated system was attached on human's wrist to detect externally applied strains and the arterial pulse using the energy stored in MSCs, charged with SCs. Noticeably, the charge/discharge behavior maintain their value even after 1000 stretching/releasing cycles, demonstrating the outstanding cycle stability and stretchability of the fabricated devices.


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