▎ 摘　　要

The attention towards flexible and wearable energy storage devices is intensifying as traditional energy storage technologies fail to satisfy the criteria for wearable applications. With its outstanding electrical and electro-chemical properties, graphene has emerged as a novel material for fabricating flexible supercapacitor electrodes. Recently, graphene-based textile fabrics have captured enormous attention for their potential application as flexible electrodes owing to their high porosity, lightweight nature, and biocompatibility characteristics. We first highlighted graphene synthesis and the underlying fabrication strategies of graphene-based fabrics. Subse-quently, the focus turned to diverse modification strategies of graphene-based fabrics with numerous functional materials. It is revealed that the modified microstructure and the synergy between graphene and these functional materials significantly boost the electrical, electrochemical, and mechanical properties of fabric electrodes. Moreover, the performance parameters (i.e., energy density, power density, cyclic stability, mechanical dura-bility, etc.) of the flexible graphene-based fabric supercapacitor are evaluated in terms of various supercapacitor configurations. The potential applications of graphene-based fabric supercapacitors and the challenges of the technology are thoroughly discussed. Finally, the environmental impact and future perspective of the technology are outlined. Hopefully, this article will lay the groundwork for future research into designing high-performance graphene-based fabric supercapacitors and even beyond.