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optical images of LED powered by MSC array. (d) normalized capacitance (C/C0) measured before and after deformation, respectively."/>

      Source: Reproduced with permission [72]. © 2017, Wiley‐VCH.

      2.2.3 3D Stretchable SCs

      The stretchability of 3D stretchable SCs are typically achieved by the configuration design, such as 3D cellular and pyramid structure that omits the utilization of elastic substrate, which is quite different with the strategy toward 1D fiber SCs and 2D planar SCs. Kirigami or patterning‐based editable technique is always employed to assemble the 3D stretchable SCs. Recently, many efforts have been devoted to design the 3D stretchable SCs, which can be divided into two types: cellular structure and editable SCs. The first one is to realize stretchability through cellular electrodes or embedding MSC arrays into a cellular structured elastic substrate. The later one represents the SCs devices arbitrary shape, which can be adjusted according to the demand of wearable electronics.

      2.2.3.1 Cellular Structure

Schematic illustrations of (a) optical images of the stretchable cellular CNT film under increasing strain. (b) CV curves under stretching. (c) Photographs of the “watch strap” powered by cellular MSC array.

      Source: Reproduced with permission [40]. © 2016, The Royal Society of Chemistry.

      (d) Optical images of honeycomb 4 × 4 MSC arrays under different stretching state. (e) Capacitance retention versus elongation (the inset figure is the CV curves for 0–150% elongation, respectively). (f) LED powered by a honeycomb MSC device under stretching.

      Source: Reproduced with permission [73]. © 2016, American Chemical Society.

      Another type of 3D stretchable SCs are fabricated by embedding several flexible MSCs devices into a cellular form thus make the MSCs stretchable. This assembled method provides a general integration way, not only in the area of energy storage, as well as energy harvester like solar cell, wireless charging units and wearable electronics such as sensors, detectors. For example, Pu et al. introduced a stretchable cellular PDMS support for flexible 4*4 MSC arrays, as shown in Figure 2.11d–f [73]. The mechanical performance of honeycomb MSC array was displayed by the optical images of the devices with strain ranging from 0% to 275%. The mechanical performance of the devices also simulated by finite element analysis (FEA). From the CV curves, the specific capacitance of single SWCNT based MSC was calculated to 1.86 F cm−3 at scan rate of 0.05 V S−1, the corresponding volumetric capacitance of the 4*4 MSC arrays was 0.15 F cm−3. Figure 2.11e showed the capacitance retention versus strains, it is very clearly seen that the capacitance of the MSC arrays kept unchanged when applied strains varying from 0 to 150%, which was also suggested by the invariable CV curves (Inset). A commercial LED lighting test driven by a honeycomb MSC devices that attach to a Nike wrist band under stretching was provided in Figure 2.11f, demonstrating the mechanical stability of the cellular MSC arrays at different stretching state. Noticeably, the voltage and current can be easily controlled through the intrinsic configuration of the cellular structure (different series or parallel interconnection modes), this also make the cellular stretchable SCs competitive among various types of stretchable SCs.

      2.2.3.2 Editable SCs

Schematic illustrations of (a) 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.
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