[1] Kou L, et al. Coaxial wet-spun yarn supercapacitors for high energy density and safe wearable electronics. Nat Commun. 2014;5:1–10.

[2] Zhang Z. Light-emitting materials for wearable electronics. Nat Rev Mater. 2022;2022(7):839–40.

[3] The many faces of wearables. Nat Electron. 2022;5:709.

[4] Liu L, Yu Y, Yan C, Li K, Zheng Z. Wearable energy-dense and power-dense supercapacitor yarns enabled by scalable graphene-metallic textile composite electrodes. Nat Commun. 2015;6:7260.

[5] Zheng F, et al. A highly sensitive CRISPR-empowered surface plasmon resonance sensor for diagnosis of inherited diseases with femtomolar-level real-time quantification. Adv Sci. 2022;9:2105231.

[6] Chen Z, et al. A CRISPR/Cas12a-empowered surface plasmon resonance platform for rapid and specific diagnosis of the Omicron variant of SARS-CoV-2. Natl Sci Rev. 2022;9:nwac 104.

[7] Xue T, et al. Ultrasensitive detection of miRNA with an antimonene-based surface plasmon resonance sensor. Nat Commun. 2019;10:28.

[8] Li C, Jia R, Yang Y, Liao G. A hierarchical helical carbon nanotube fiber artificial ligament. Adv Fiber Mater. 2023;2023(5):1549–51.

[9] Zheng Y, et al. Electrochemical exfoliation and growth of nickel–cobalt layered double hydroxides@black phosphorus hetero-nanostructure textiles for robust foldable supercapacitors. Adv Funct Mater. 2024;2401738

[10] Zhu X, et al. Microfluidic-assembled covalent organic frameworks@Ti3C2Tx MXene vertical fibers for high-performance electrochemical supercapacitors. Adv Mater. 2023;35:2307186.

[11] Qu G, et al. A fiber supercapacitor with high energy density based on hollow graphene/conducting polymer fiber electrode. Adv Mater. 2016;28:3646–52.

[12] Ren J, et al. Twisting carbon nanotube fibers for both wire-shaped micro-supercapacitor and micro-battery. Adv Mater. 2013;25:1155–9.

[13] Lima N, et al. Carbon threads sweat-based supercapacitors for electronic textiles. Sci Rep. 2020;10:1–9.

[14] Choi C, et al. Stretchable, weavable coiled carbon nanotube/MnO2/polymer fiber solid-state supercapacitors. Sci Rep. 2015;5:1–6.

[15] Zhai S, Chen Y. Graphene-based fiber supercapacitors. Acc Mater Res. 2022;3:922–34.

[16] Yu D, et al. Scalable synthesis of hierarchically structured carbon nanotube-graphene fibres for capacitive energy storage. Nat Nanotechnol. 2014;9:555–62.

[17] Lu Z, et al. Carbon nanotube based fiber supercapacitor as wearable energy storage. Front Mater. 2019;2019(6):1–14.

[18] Guan T, et al. Recent progress of graphene fiber/fabric supercapacitors: From building block architecture, fiber assembly, and fabric construction to wearable applications. Adv Fiber Mater. 2023;5:896–927.

[19] Lee S, An GH. Interface engineering of carbon fiber-based electrode for wearable energy storage devices. Adv Fiber Mater. 2023;5:1749–58.

[20] Zhou Y, Guan F, Zhao F, Shen Y, Bao L. High-energy-density graphene hybrid flexible fiber supercapacitors. Batter Supercaps. 2023;6:e202200536.

[21] Zhu X, et al. Vertical-aligned and ordered-active architecture of heterostructured fibers for high electrochemical capacitance. Adv Fiber Mater. 2024;6:312–28.

[22] Padmajan SS, et al. Interface-confined high crystalline growth of semiconducting polymers at graphene fibers for high-performance wearable supercapacitors. ACS Nano. 2017;11:9424–34.

[23] Tian J, Cui N, Chen P, Guo K, Chen X. High-performance wearable supercapacitors based on PANI/N-CNT@CNT fiber with a designed hierarchical core-sheath structure. J Mater Chem A Mater. 2021;9:20635–44.

[24] Salman A, et al. Tungsten nitride-coated graphene fibers for high-performance wearable supercapacitors. Nanoscale. 2020;12:20239–49.

[25] Lim L, et al. All-in-one graphene based composite fiber: Toward wearable supercapacitor. ACS Appl Mater Interfaces. 2017;9:39576–83.

[26] Cai W, et al. Transition metal sulfides grown on graphene fibers for wearable asymmetric supercapacitors with high volumetric capacitance and high energy density. Sci Rep. 2016;6:1–9.

[27] Yuan S, et al. Recent progress on transition metal oxides as advanced materials for energy conversion and storage. Energy Storage Mater. 2021;42:317–69.

[28] Teng XL, Sun XT, Guan L, Hu H, Wu MB. Self-supported transition metal oxide electrodes for electrochemical energy storage. Tungsten. 2020;2:337–61.

[29] Lei Z, et al. Recent advances of layered-transition metal oxides for energy-related applications. Energy Storage Mater. 2021;36:514–50.

[30] Wei ZY, et al. Progress in ceramic materials and structure design toward advanced thermal barrier coatings. J Adv Ceram. 2022;11:985–1068.

[31] Delbari SA, et al. Transition metal oxide-based electrode materials for flexible supercapacitors: A review. J Alloys Compd. 2021;857:158281.

[32] Georgakilas V, et al. Noncovalent functionalization of graphene and graphene oxide for energy materials, biosensing, catalytic, and biomedical applications. Chem Rev. 2016;116:5464–519.

[33] Ahn J, et al. Nanotransfer-on-things: From rigid to stretchable nanophotonic devices. ACS Nano. 2023;17:5935.

[34] Ahn J, et al. Nanoscale three-dimensional fabrication based on mechanically guided assembly. Nat Commun. 2023;14:833.

[35] Liu LY, et al. Synthesis of Co–Ni oxide microflowers as a superior anode for hybrid supercapacitors with ultralong cycle life. Chin Chem Lett. 2017;28:206–12.

[36] Karaca E, Gökcen D, Pekmez NÖ, Pekmez K. Electrochemical synthesis of PPy composites with nanostructured MnOx, CoOx, NiOx, and FeOx in acetonitrile for supercapacitor applications. Electrochim Acta. 2019;305:502–13.

[37] Peng J, Jeffrey SG. A figure of merit for flexibility. Science. 2019;366:690–1.

[38] Chen YS, et al. Microscopic mechanism for unipolar resistive switching behaviour of nickel oxides. J Phys D Appl Phys. 2012;45:065303.

[39] Wang M, et al. Efficiently enhancing electrocatalytic activity of α-MnO2 nanorods/N-doped ketjenblack carbon for oxygen reduction reaction and oxygen evolution reaction using facile regulated hydrothermal treatment. Catalysts. 2018;8:138.

[40] Li XC, et al. Coherent nanoscale cobalt/cobalt oxide heterostructures embedded in porous carbon for the oxygen reduction reaction. RSC Adv. 2018;8:28625–31.

[41] Wang R, Wu J. Structure and basic properties of ternary metal oxides and their prospects for application in supercapacitors. In: Metal oxides in supercapacitors. Elsevier Inc.; 2017. p. 99–132.

[42] Xie J, et al. Puzzles and confusions in supercapacitor and battery: theory and solutions. J Power Sour. 2018;401:213–23.

[43] Sahoo S, Kumar R, Joanni E, Singh RK, Shim JJ. Advances in pseudocapacitive and battery-like electrode materials for high performance supercapacitors. J Mater Chem A Mater. 2022;10:13190–240.

[44] Reddy Inta H, Koppisetti HVSRM, Ghosh S, Roy A, Mahalingam V. Ni3Se4 nanostructure as a battery-type positive electrode for hybrid capacitors. ChemElectroChem. 2023;10:1–11.

[45] Kushwaha V, Mandal KD, Gupta A, Singh P. Ni0.5Co0.5S nano-chains: a high-performing intercalating pseudocapacitive electrode in asymmetric supercapacitor (ASC) mode for the development of large-scale energy storage devices. Dalton Trans. 2024;53:5435–52.

[46] Choi C, et al. Improvement of system capacitance via weavable superelastic biscrolled yarn supercapacitors. Nat Commun. 2016;7:1–8.

[47] Meddings N, et al. Application of electrochemical impedance spectroscopy to commercial Li-ion cells: A review. J Power Sour. 2020;480:228742.

[48] Pech D, et al. Ultrahigh-power micrometre-sized supercapacitors based on onion-like carbon. Nat Nanotechnol. 2010;5:651–4.

[49] El-Kady MF, Kaner RB. Scalable fabrication of high-power graphene micro-supercapacitors for flexible and on-chip energy storage. Nat Commun. 2013;4:1475.

[50] Kim MS, et al. Skin-like omnidirectional stretchable platform with negative Poisson’s ratio for wearable strain–pressure simultaneous sensor. Adv Funct Mater. 2023;33:1–10.

[51] Jung Y, et al. Spherical micro/nano hierarchical structures for energy and water harvesting devices. Small Methods. 2022;2200248:1–11.

[52] Zhao ZJ, et al. Wafer-scale, highly uniform, and well-arrayed suspended nanostructures for enhancing the performance of electronic devices. Nanoscale. 2022;14:1136–43.

[53] Jeong Y, et al. Biomimetic, programmable, and part-by-part maneuverable single-body shape-morphing film. Adv Intell Syst. 2023;5:1–12.

[54] Zhao ZJ, et al. Large-area nanogap-controlled 3D nanoarchitectures fabricated via layer-by-layer nanoimprint. ACS Nano. 2021;15:503–14.

[55] Zhao ZJ, et al. Shape-controlled and well-arrayed heterogeneous nanostructures via melting point modulation at the nanoscale. ACS Appl Mater Interfaces. 2021;13:3358–68.

[56] Ahn J, et al. All-recyclable triboelectric nanogenerator for sustainable ocean monitoring systems. Adv Energy Mater. 2022;2201341:1–11.

[57] Ahn J, et al. Morphology-controllable wrinkled hierarchical structure and its application to superhydrophobic triboelectric nanogenerator. Nano Energy. 2021;85:105978.

[58] Ahn J, et al. Nanoribbon yarn with versatile inorganic materials. Small. 2024. https://doi-org-ssl.oca.korea.ac.kr/10.1002/smll.202311736.