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2.12 (a) Schematics of a 3D stretchable SC. (b) Optical images of the CNT film being gradually stretched along the z axis. (c) GCD curves with increasing strains from 0% to 16% along the x or y axis.

      Source: Reproduced with permission [74]. © 2016, The Royal Society of Chemistry.

      (d) Schematics for the assembling process of stretchable SCs. (e) Digital images of 3D SCs under different strain tests. (f) Lighting test driven by tailored paper‐cutting SC.

      Source: Reproduced with permission [41]. © 2017, Wiley‐VCH.

      By the kirigami technique, the SCs can be designed with stretchability, as shown in Figure 2.12d [41]. In comparison with prestrain‐release based stretchable SCs, the form and shape of editable are more free. Cellular structure, pyramid structure, living‐hinge structure etc. can be easily obtained and the stretchable direction are not restricted. Traditional sandwiched SCs always use gel electrolyte as the separator, which caused the weak intermolecular interaction thus cannot effectively serve as a separator to prevent short circuit of SCs during editing process. Therefore, the authors employed nanocellulose fibers as separator and PVA/H3PO4 as gel electrolyte. MnO2 nanowires@CNT served as electrode materials. Figure 2.12e displayed the photography of fabricated honeycomb shaped SCs with increasing strain varying from 0% to 810%. The fabricated honeycomb shaped SCs exhibited a specific capacitance of 227.2 mF cm−2 and no degradation of electrochemical performance when applied a strain of 500%, providing an excellent mechanical stability of the editable SCs. In addition, nearly 98% of initial capacitance of the honeycomb shaped editable SCs interlocked by PU fibers was remained even after 10 000 stretch‐and‐release cycles under reversible 400% tensile strain. As mentioned above, the editable SCs endow advantages of tunable voltage by different interconnection in parallel and/or series. As a proof of concept, four SCs were connected in series and tailored into delicate and artistic patterns to power a LED (Figure 2.12f), suggesting that editable SCs can realize more complicated and free patterns with high stretchability.

      With the development of the highly stretchable SC, its application was expanded to many areas, including portable, wearable energy storage, electronic skins, sensors, detectors, implantable medical devices, which also raise new demands to the energy storage, such as compressible, self‐healable etc. In recent years, many attempts have been made to incorporate such functions into stretchable energy storage.

      2.3.1 Compressible SCs

Schematic illustrations of (a) synthesizing PANI at SWCNTs sponge composite electrodes. (b) Cross-sectional scheme of the fabricated PANI@SWCNTs sponge based SCs. (c) Real-time optical images of the SCs under compressing. (d) CV curves of the compressible SCs with increasing strains from 0% to 60%. (e) Photography of the patterned d Au current collector on PET plate. (f–h) Lighting test driven by four SCs showing the compressing and recovering process.

      Source: Reproduced with permission [75]. © 2015, Wiley‐VCH.

      2.3.2 Self‐Healable SCs


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