Fig. 1. Schematic illustrations of energy storage mechanisms of (a) electric double-layer capacitor, (b) pseudocapacitor, (c) hybrid capacitor. (d) Structure diagram of supercapacitor.

Fig. 2. Design ideas of stretchable supercapacitor: Elastic polymer, stretchable structure, and elastic polymer + stretchable structure.

Fig. 3. Stretchable electrodes/supercapacitors based on elastic polymer: (a), (b) PDMS^[36,50]; (c) Ecoflex^[52]; (d) PU^[21]; (e) elastic fiber^[55].

Fig. 4. Stretchable supercapacitors based on stretchable structure: (a) Helical structure^[66]; (b) wave structure^[68]; (c) fabric structure^[71]; (d) serpentine structure^[75]; (e)−(g) net structure^[45,76,78].

Fig. 5. Schematic illustrations of stretchable supercapacitors: (a) Fabric structure stretchable supercapacitors; (b) stretchable fabric structure; (c) non-stretchable fabric structure; (d) image of stretchable fabric structure; (e) capacity retention after different numbers of stretch/release cycles under different strains (10%, 20%, and 30%) at a current density of 8 A/g (the inset presents the images of the hybrid supercapacitor device during stretching cycles); (f) schematic of elbow-fitted supercapacitor; images of two supercapacitors connected in series for the illumination of an elbow-fitted LED for (g) stretching and (h) bending. (i) Two devices connected in series for the illumination of a set of 40 LEDs with a parallel "DHU" pattern^[81].

Fig. 6. Comparison of the stretchable supercapacitor with reported supercapacitors with respect to the tensile recovery, stretching cyclic stability, and electrochemical properties, where C0 and C correspond to the specific capacities before and after stretching cycles, respectively.

Fig. 7. Stretchable supercapacitors based on elastic polymer and stretchable structure: (a), (b) Elastic polymer and wave structure^[57,92]; (c) elastic polymer and helical structure^[94]; (d) elastic polymer and fabric structure^[97]; (e) elastic polymer and net structure^[59].

Fig. 8. Multifunction stretchable supercapacitors: (a) Self-powered^[47]; (b) sensing^[73]; (c), (d) transparent^[87,120].

Fig. 9. Multifunction stretchable supercapacitors: (a)−(e) ultrathin^[112]; (f) self-healing^[90].

Fig. 10. (a) Illustration of the preparation of Agar/HPAAm double-net hydrogel; (b) the recovery performance of Agar/HPAAm hydrogel and Agar/PAAm hydrogel under different stretching conditions^[126]; (c) schematic configuration of the intrinsically stretcha-ble supercapacitor using highly stretchable gel electrolyte^[105].