active materials utilized in energy storage suffer from poor elasticity or relatively low electrochemical performance. In previous studies, three major stretchable structures have been proposed: coiled fiber structure, [6][7][8] wavy structure, [5,9,10] and islandbridge structure. [11][12][13] The active materials applied in these structures should be easily handled and tough. For use in wavy and island-bridge structures soft materials are required. Coating, transferring, in situ deposition, or polymerization of active materials onto a stretchable substrate such as fabric, polymer, and paper have been devised for the electrodes of energy storage and conversion devices; but mostly declaring a low elasticity. [14,15] A fiber-based or wire-shaped device can be easily integrated into stretchable yarns or fabrics to fulfill a more practical demand of wearable energy storage, conversation, or transition in our daily life. The electrochemical property and stretchability both play a vital role in the fiber-based supercapacitors and batteries. [16][17][18] Carbon nanotubes (CNTs) are widely used electrode materials that possess extraordinary physical and chemical properties, and they have also been verified to assemble into fiber formation by using solid-state spun or wet-spun techniques. [19] Fibers formed by pristine CNT have been demonstrated with high electrical conductivity and superior mechanical properties, although the intrinsic electrochemical performances of CNT fibers are not outstanding enough. [20][21][22][23] A possible explanation of this behavior lies in the strong interaction between carbon nanotubes, which, while increasing the packing density inside fibers, does not allow high ion accessibility. To reduce the dense stacking, CNT/graphene composites have been proposed and fabricated to increase inner porosity. [24,25] On the other hand, coiled structure and elastic polymer fibers have been reported previously as the most popular approach or material to enhance the stretchability of fibers and films, which have been incorporated with various active materials such as carbon nanomaterials (e.g., nanotubes, graphene), metal oxide nanoparticles, and conductive polymers. [6,15,[26][27][28] The reported coiled fiber supercapacitor only afforded up to a strain of 150% to maintain its performance, [6] although the capacitance could be achieved as high as 382 mF cm −2 . [28] Coincidentally, the pseudocapacitance material, deposited carbon nanotube sheets wrapped coaxial elastic fiber, demonstrated a high specific capacitance as well as a strain of 400% without damages to the properties. [27] In this paper, we explore a novel approach to fabricate nanostructured carbon nanotube/graphene/conducting polymer The demands for wearable technologies continue to grow and novel approaches for powering these devices are being enabled by the advent of new electromaterials and novel fabrication strategies. Herein, a novel approach is reported to develop superelastic wet-spun hybrid carbon nanotube graphene fibers followed by e...
