Recent development on the design, preparation, and application of stretchable conductors for flexible energy harvest and storage devices

Minhan Cheng; Ke Tian; Tian Qin; Qianyang Li; Hua Deng; Qiang Fu

doi:10.1002/sus2.204

SusMat ›› 2024, Vol. 4 ›› Issue (4) : e204 DOI: 10.1002/sus2.204

REVIEW

Recent development on the design, preparation, and application of stretchable conductors for flexible energy harvest and storage devices

Author information +

History +

PDF

Abstract

The intensifying energy crisis has made it urgent to develop robust and reliable next-generation energy systems. Except for conventional large-scale energy sources, the imperceptible and randomly distributed energy embedded in daily life awaits comprehensive exploration and utilization. Harnessing the latent energy has the potential to facilitate the further evolution of soft energy systems. Compared with rigid energy devices, flexible energy devices are more convenient and suitable for harvesting and storing energy from dynamic and complex structures such as human skin. Stretchable conductors that are capable of withstanding strain (≫1%) while sustaining stable conductive pathways are prerequisites for realizing flexible electronic energy devices. Therefore, understanding the characteristics of these conductors and evaluating the feasibility of their fabrication strategies are particularly critical. In this review, various preparation methods for stretchable conductors are carefully classified and analyzed. Furthermore, recent progress in the application of energy harvesting and storage based on these conductors is discussed in detail. Finally, the challenges and promising opportunities in the development of stretchable conductors and integrated flexible energy devices are highlighted, seeking to inspire their future research directions.

Keywords

energy harvesting / energy storage / fabrication strategies / stretchable conductors

Cite this article

Download citation ▾

Minhan Cheng, Ke Tian, Tian Qin, Qianyang Li, Hua Deng, Qiang Fu. Recent development on the design, preparation, and application of stretchable conductors for flexible energy harvest and storage devices. SusMat, 2024, 4(4): e204 DOI:10.1002/sus2.204

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	DeAngelo J, Azevedo I, Bistline J, et al. Energy systems in scenarios at net-zero CO₂ emissions. Nat Commun. 2021; 12: 6096.

[2]	Goldthau A, Tagliapietra S. Energy crisis: five questions that must be answered in 2023. Nature. 2022; 612: 627-630.

[3]	Pedersen TT, Gøtske EK, Dvorak A, et al. Long-term implications of reduced gas imports on the decarbonization of the European energy system. Joule. 2022; 6: 1566-1580.

[4]	Guan S, Li J, Wang Y, et al. Multifunctional MOF-derived Au, Co-doped porou. carbon electrode for a wearable sweat energy harvesting-storage hybrid system. Adv Mater. 2023; 35: 2304465.

[5]	Huang L, Lin S, Xu Z, et al. Fiber-based energy conversion devices for human-body energy harvesting. Adv Mater. 2020; 32: 1902034.

[6]	Liu R, Wang ZL, Fukuda K, et al. Flexible self-charging power sources. Nat Rev Mater. 2022; 7: 870-886.

[7]	Liu Y, Zhang S, Zhou Y, et al. Advanced wearable thermocells for body heat harvesting. Adv Energy Mater. 2020; 10: 2002539.

[8]	Song Y, Min J, Yu Y, et al. Wireless battery-free wearable sweat sensor powered by human motion. Sci Adv. 2020; 6: eaay9842.

[9]	Yu Y, Nassar J, Xu C, et al. Biofuel-powered soft electronic skin with multiplexed and wireless sensing for human-machine interfaces. Sci Rob. 2020; 5: eaaz7946.

[10]	Ershad F, Patel S, Yu C. Wearable bioelectronics fabricated in situ on skins. npj Flexible Electron. 2023; 7: 32.

[11]	Liu S, Rao Y, Jang H, et al. Strategies for body-conformable electronics. Matter. 2022; 5: 1104-1136.

[12]	Matsuhisa N, Chen X, Bao Z, et al. Materials and structural designs of stretchable conductors. Chem Soc Rev. 2019; 48: 2946-2966.

[13]	Wang C, Yokota T, Someya T. Natural biopolymer-based biocompatible conductors for stretchable bioelectronics. Chem Rev. 2021; 121: 2109-2146.

[14]	Chen ZH, Fang R, Li W, et al. Stretchable transparent conductors: from micro/macromechanics to applications. Adv Mater. 2019; 31: 1900756.

[15]	Kim Y, Kweon OY, Won Y, et al. Deformable and stretchable electrodes for soft electronic devices. Macromol Res. 2019; 27: 625-639.

[16]	Nie M, Li B, Hsieh Y-L, et al. Stretchable one-dimensional conductors for wearable applications. ACS Nano. 2022; 16: 19810-19839.

[17]	Wang B, Facchetti A. Mechanically flexible conductors for stretchable and wearable E-skin and E-textile devices. Adv Mater. 2019; 31: 1901408.

[18]	Wang L, Yi Z, Zhao Y, et al. Stretchable conductors for stretchable field-effect transistors and functional circuits. Chem Soc Rev. 2023; 52: 795-835.

[19]	Gong X, Yang Q, Zhi C, et al. Stretchable energy storage devices: from materials and structural design to device assembly. Adv Energy Mater. 2021; 11(15): 2003308.

[20]	Mackanic DG, Kao M, Bao Z. Enabling deformable and stretchable batteries. Adv Energy Mater. 2020; 10: 2001424.

[21]	Yan C, Lee PS. Stretchable energy storage and conversion devices. Small. 2014; 10: 3443-3460.

[22]	Zhai Q, Xiang F, Cheng F, et al. Recent advances in flexible/stretchable batteries and integrated devices. Energy Storage Mater. 2020; 33: 116-138.

[23]	Choi S, Han SI, Kim D, et al. High-performance stretchable conductive nanocomposites: materials, processes, and device applications. Chem Soc Rev. 2019; 48: 1566-1595.

[24]	Peng S, Yu Y, Wu S, et al. Conductive polymer nanocomposites for stretchable electronics: material selection, design, and applications. ACS Appl Mater Interfaces. 2021; 13: 43831-43854.

[25]	Zhang Q, Liang J, Huang Y, et al. Intrinsically stretchable conductors and interconnects for electronic applications. Mater Chem Front. 2019; 3: 1032-1051.

[26]	He J, Lu C, Jiang H, et al. Scalable production of high-performing woven lithium-ion fibre batteries. Nature. 2021; 597: 57-63.

[27]	Choi S, Han SI, Jung D, et al. Highly conductive, stretchable and biocompatible Ag-Au core-sheath nanowire composite for wearable and implantable bioelectronics. Nat Nanotechnol. 2018; 13: 1048-1056.

[28]	Gu M, Song W-J, Hong J, et al. Stretchable batteries with gradient multilayer conductors. Sci Adv. 2019; 5: eaaw1879.

[29]	Hu H, Wang S, Wang S, et al. Aligned silver nanowires enabled highly stretchable and transparent electrodes with unusual conductive property. Adv Funct Mater. 2019; 29: 1902922.

[30]	Huang Y, Yu B, Zhang L, et al. Highly stretchable conductor by self-assembling and mechanical sintering of a 2D liquid metal on a 3D polydopamine-modified polyurethane sponge. ACS Appl Mater Interfaces. 2019; 11: 48321-48330.

[31]	Zhang M, Gong J, Chang H, et al. Bio-inspired differential capillary migration of aqueous liquid metal ink for rapid fabrication of high-precision monolayer and multilayer circuits. Adv Funct Mater. 2023; 33: 2215050.

[32]	Guan Y-S, Zhang Z, Tang Y, et al. Kirigami-inspired nanoconfined polymer conducting nanosheets with 2000% stretchability. Adv Mater. 2018; 30: 1706390.

[33]	Ho MD, Liu Y, Dong D, et al. Fractal gold nanoframework for highly stretchable transparent strain-insensitive conductors. Nano Lett. 2018; 18: 3593-3599.

[34]	Liu W, Chen J, Chen Z, et al. Stretchable lithium-ion batteries enabled by device-scaled wavy structure and elastic-sticky separator. Adv Energy Mater. 2017; 7: 1701076.

[35]	Shi C, Wang T, Liao X, et al. Accordion-like stretchable Li-ion batteries with high energy density. Energy Storage Mater. 2019; 17: 136-142.

[36]	Li J, Kim J-K. Percolation threshold of conducting polymer composites containing 3D randomly distributed graphite nanoplatelets. Compos Sci Technol. 2007; 67: 2114-2120.

[37]	Wang B, Facchetti A. Mechanically flexible conductors for stretchable and wearable E-skin and E-textile devices. Adv Mater. 2019; 31: 1-10.

[38]	Lu X, Zhang Y, Zheng Z. Metal-based flexible transparent electrodes: challenges and recent advances. Adv Electron Mater. 2021; 7: 200121.

[39]	Park M, Im J, Shin M, et al. Highly stretchable electric circuits from a composite material of silver nanoparticles and elastomeric fibres. Nat Nanotechnol. 2012; 7: 803-809.

[40]	Tian K, Chen C, Li Q, et al. Evaporation-induced closely-packing of core-shell PDMS@Ag microspheres enabled stretchable conductor with ultra-high conductance. Adv Funct Mater. 2023; 33: 2308799.

[41]	Jiang Z, Chen N, Yi Z, et al. A 1.3-micrometre-thick elastic conductor for seamless on-skin and implantable sensors. Nat Electron. 2022; 5: 784-793.

[42]	Jia Y, Zhang L, Qin M, et al. Highly efficient self-healable and robust fluorinated polyurethane elastomer for wearable electronics. Chem Eng J. 2022; 430: 133081.

[43]	Zhang M, Zhao M, Jian M, et al. Printable smart pattern for multifunctional energy-management E-textile. Matter. 2019; 1: 168-179.

[44]	Mone M, Kim Y, Darabi S, et al. Mechanically adaptive mixed ionic-electronic conductors based on a polar polythiophene reinforced with cellulose nanofibrils. ACS Appl Mater Interfaces. 2023; 15: 28300-28309.

[45]	Rai R, Tallawi M, Grigore A, et al. Synthesis, properties and biomedical applications of poly(glycerol sebacate) (PGS): a review. Prog Polym Sci. 2012; 37: 1051-1078.

[46]	Han WB, Ko G-J, Lee K-G. et al. Ultra-stretchable and biodegradable elastomers for soft, transient electronics. Nat Commun. 2023; 14: 2263.

[47]	Liu K, Tran H, Feig VR, et al. Biodegradable and stretchable polymeric materials for transient electronic devices. MRS Bull. 2020; 45: 96-102.

[48]	Carneiro MR, Majidi C, Tavakoli M. Gallium-based liquid-solid biphasic conductors for soft electronics. Adv Funct Mater. 2023; 33: 2306453.

[49]	Kim SH, Seo H, Kang J, et al. An ultrastretchable and self-healable nanocomposite conductor enabled by autonomously percolative electrical pathways. ACS Nano. 2019; 13: 6531-6539.

[50]	Wang Y, Lee S, Yokota T, et al. A durable nanomesh on-skin strain gauge for natural skin motion monitoring with minimum mechanical constraints. Sci Adv. 2020; 6: eabb7043.

[51]	Sekitani T, Noguchi Y, Hata K, et al. A rubberlike stretchable active matrix using elastic conductors. Science. 2008; 321: 1468-1472.

[52]	Lee B, Cho H, Moon S, et al. Omnidirectional printing of elastic conductors for three-dimensional stretchable electronics. Nat Electron. 2023; 6: 307-318.

[53]	Sekitani T, Nakajima H, Maeda H, et al. Stretchable active-matrix organic light-emitting diode display using printable elastic conductors. Nat Mater. 2009; 8: 494-499.

[54]	Chen Z, Ren W, Gao L, et al. Three-dimensional flexible and conductive interconnected graphene networks grown by chemical vapour deposition. Nat Mater. 2011; 10: 424-428.

[55]	Jung D, Lim C, Park C, et al. Adaptive self-organization of nanomaterials enables strain-insensitive resistance of stretchable metallic nanocomposites. Adv Mater. 2022; 34: 2200980.

[56]	Jung D, Kim Y, Lee H, et al. Metal-like stretchable nanocomposite using locally-bundled nanowires for skin-mountable devices. Adv Mater. 2023; 35: 2303458.

[57]	Matsuhisa N, Inoue D, Zalar P, et al. Printable elastic conductors by in-situ formation of silver nanoparticles from silver flakes. Nat Mater. 2017; 16: 834-840.

[58]	Kim Y, Zhu J, Yeom B, et al. Stretchable nanoparticle conductors with self-organized conductive pathways. Nature. 2013; 500: 59-63.

[59]	Ajmal CM, Cha S, Kim W, et al. Invariable resistance of conductive nanocomposite over 30% strain. Sci Adv. 2022; 8: eabn3365.

[60]	Lee W, Kim H, Kang I, et al. Universal assembly of liquid metal particles in polymers enables elastic printed circuit board. Science. 2022; 378: 637-641.

[61]	Feig VR, Tran H, Lee M, et al. Mechanically tunable conductive interpenetrating network hydrogels that mimic the elastic moduli of biological tissue. Nat Commun. 2018; 9: 2740.

[62]	Bai Y, Li W, Tie Y, et al. A stretchable polymer conductor through the mutual plasticization effect. Adv Mater. 2023; 35: 2303245.

[63]	Jung D, Lim C, Shim HJ, et al. Highly conductive and elastic nanomembrane for skin electronics. Science. 2021; 373: 1022-1026.

[64]	Xiong J, Li S, Ye Y, et al. A deformable and highly robust ethyl cellulose transparent conductor with a scalable silver nanowires bundle micromesh. Adv Mater. 2018; 30: 1802803.

[65]	Liu S, Shah DS, Kramer-Bottiglio R. Highly stretchable multilayer electronic circuits using biphasic gallium-indium. Nat Mater. 2021; 20: 851-858.

[66]	Miyamoto A, Lee S, Cooray NF, et al. Inflammation-free, gas-permeable, lightweight, stretchable on-ski. electronics with nanomeshes. Nat Nanotechnol. 2017; 12: 907-913.

[67]	Fan YJ, Li X, Kuang SY, et al. Highly robust, transparent, and breathable epidermal electrode. ACS Nano. 2018; 12: 9326-9332.

[68]	Zhuang Q, Ma Z, Gao Y, et al. Liquid-metal-superlyophilic and conductivity-strain-enhancing scaffold for permeable superelastic conductors. Adv Funct Mater. 2021; 31: 2105587.

[69]	Li Y, Fang T, Zhang J, et al. Ultrasensitive and ultrastretchable electrically self-healing conductors. PNAS. 2023; 120: e2300953120.

[70]	Lin Y, Fang T, Bai C, et al. Ultrastretchable electrically self-healing conductors based on silver nanowire/liquid metal microcapsule nanocomposites. Nano Lett. 2023; 23: 11174-11183.

[71]	Ajmal CM, Benny AP, Jeon W, et al. In-situ reduced non-oxidized copper nanoparticles in nanocomposites with extraordinary high electrical and thermal conductivity. Mater Today. 2021; 48: 59-71.

[72]	Feig VR, Tran H, Lee M, et al. An electrochemical gelation method for patterning conductive PEDOT:PSS hydrogels. Adv Mater. 2019; 31: 1902869.

[73]	Wang Y, Zhu C, Pfattner R, et al. A highly stretchable, transparent, and conductive polymer. Sci Adv. 2017; 3: e1602076.

[74]	Chun S, Kim DW, Baik S, et al. Conductive and stretchable adhesive electronics with miniaturized octopus-like suckers against dry/wet skin for biosignal monitoring. Adv Funct Mater. 2018; 28: 1805224.

[75]	Muth JT, Vogt DM, Truby RL, et al. Embedded 3D printing of strain sensors within highly stretchable elastomers. Adv Mater. 2014; 26: 6307-6312.

[76]	Lu N, Lu C, Yang S, et al. Highly sensitive skin-mountable strain gauges based entirely on elastomers. Adv Funct Mater. 2012; 22: 4044-4050.

[77]	Boland CS, Khan U, Ryan G, et al. Sensitive electromechanical sensors using viscoelastic graphene-polymer nanocomposites. Science. 2016; 354: 1257-1260.

[78]	Ata S, Kobashi K, Yumura M, et al. Mechanically durable and highly conductive elastomeric composites from long single-walled carbon nanotubes mimicking the chain structure of polymers. Nano Lett. 2012; 12: 2710-2716.

[79]	Shin MK, Oh J, Lima M, et al. Elastomeric conductive composites based on carbon nanotube forests. Adv Mater. 2010; 22: 2663-2667.

[80]	Ajmal CM, Bae S, Baik S. A superior method for constructing electrical percolation network of nanocomposite fibers: in situ thermally reduced silver nanoparticles. Small. 2019; 15: 1803255.

[81]	Tang Y, Gong S, Chen Y, et al. Manufacturable conducting rubber ambers and stretchable conductors from copper nanowire aerogel monoliths. ACS Nano. 2014; 8: 5707-5714.

[82]	Catenacci MJ, Reyes C, Cruz MA, et al. Stretchable conductive composites from Cu-Ag nanowire felt. ACS Nano. 2018; 12: 3689-3698.

[83]	Chun K-Y, Oh Y, Rho J, et al. Highly conductive, printable and stretchable composite films of carbon nanotubes and silver. Nat Nanotechnol. 2010; 5: 853-857.

[84]	Suh D, Faseela KP, Kim W, et al. Electron tunneling of hierarchically structured silver nanosatellite particles for highly conductive healable nanocomposites. Nat Commun. 2020; 11: 2252.

[85]	Matsuhisa N, Kaltenbrunner M, Yokota T, et al. Printable elastic conductors with a high conductivity for electronic textile applications. Nat Commun. 2015; 6: 7461.

[86]	Zhu B, Gong S, Cheng W. Softening gold for elastronics. Chem Soc Rev. 2019; 48: 1668-1711.

[87]	Yang Y, Deng H, Fu Q. Recent progress on PEDOT:PSS based polymer blends and composites for flexible electronics and thermoelectric devices. Mater Chem Front. 2020; 4: 3130-3152.

[88]	Xie J, Ewing S, Boyn J-N, et al. Intrinsic glassy-metallic transport in an amorphous coordination polymer. Nature. 2022; 611: 479-484.

[89]	Tang H, Liang Y, Liu C, et al. A solution-processed n-type conducting polymer with ultrahigh conductivity. Nature. 2022; 611: 271-277.

[90]	Yamamoto S, Yamashita R, Kubota C, et al. Orthogonal electric and ionic conductivities in the thin film of a thiophene-thiophene block copolymer. J Mater Chem C. 2023; 11: 2484-2493.

[91]	Kayser LV, Lipomi DJ. Stretchable conductive polymers and composites based on PEDOT and PEDOT:PSS. Adv Mater. 2019; 31: 1806133.

[92]	Shi H, Liu C, Jiang Q, et al. Effective approaches to improve the electrical conductivity of PEDOT:PSS: a review. Adv Electron Mater. 2015; 1: 1500017.

[93]	Noh J-S. Highly conductive and stretchable poly(dimethylsiloxane):poly(3, 4-ethylenedioxythiophene):poly(styrene sulfonic acid) blends for organic interconnects. RSC Adv. 2014; 4: 1857-1863.

[94]	Choong C-L, Shim M-B, Lee B-S. et al. Highly stretchable resistive pressure sensors using a conductive elastomeric composite on a micropyramid array. Adv Mater. 2014; 26: 3451-3458.

[95]	Li P, Du D, Guo L, et al. Stretchable and conductive polymer films for high-performance electromagnetic interference shielding. J Mater Chem C. 2016; 4: 6525-6532.

[96]	Li P, Sun K, Ouyang J. Stretchable and conductive polymer films prepared by solution blending. ACS Appl Mater Interfaces. 2015; 7: 18415-18423.

[97]	Dong L, Wang M, Wu J, et al. Stretchable, adhesive, self-healable, and conductive hydrogel-based deformable triboelectric nanogenerator for energy harvesting and human motion sensing. ACS Appl Mater Interfaces. 2022; 14: 9126-9137.

[98]	Wang Y, Gao C, Zhao C, et al. Engineering PEDOT:PSS/PEG fibers with a textured surface toward comprehensive personal thermal management. ACS Appl Mater Interfaces. 2023; 15: 17175-17187.

[99]	Bade SGR, Shan X, Phong Tran H, et al. Stretchable light-emitting diodes with organometal-halide-perovskite-polymer composite emitters. Adv Mater. 2017; 29: 1607053.

[100]

Wu Q, Wei J, Xu B, et al. A robust, highly stretchable supramolecular polymer conductive hydrogel with self-healability and thermo-processability. Sci Rep. 2017; 7: 41566.

[101]

Li T, Li X, Yang J, et al. Healable ionic conductors with extremely low-hysteresis and high mechanical strength enabled by hydrophobic domain-locked reversible interactions. Adv Mater. 2023; 35: 2307990.

[102]

Jiang Y, Zhang Z, Wang Y-X, et al. Topological supramolecular network enabled high-conductivity, stretchable organic bioelectronics. Science. 2022; 375: 1411-1417.

[103]

Wang D, Zhang Y, Lu X, et al. Chemical formation of soft metal electrodes for flexible and wearable electronics. Chem Soc Rev. 2018; 47: 4611-4641.

[104]

Wang Y, Li X, Hou Y, et al. A review on structures, materials and applications of stretchable electrodes. Front Mater Sci. 2021; 15: 54-78.

[105]

Cheng T, Zhang Y, Lai W-Y, et al. Stretchable thin-film electrodes for flexible electronics with high deformability and stretchability. Adv Mater. 2015; 27: 3349-3376.

[106]

Zhang Z, Wang W, Jiang Y, et al. High-brightness all-polymer stretchable LED with charge-trapping dilution. Nature. 2022; 603: 624-630.

[107]

Matsuhisa N, Niu S, O’Neill SJK, et al. High-frequency and intrinsically stretchable polymer diodes. Nature. 2021; 600: 246-252.

[108]

Kim DC, Shim HJ, Lee W, et al. Material-based approaches for the fabrication of stretchable electronics. Adv Mater. 2020; 32: 1902743.

[109]

Kang S, Cho S, Shanker R, et al. Transparent and conductive nanomembranes with orthogonal silver nanowire arrays for skin-attachable loudspeakers and microphones. Sci Adv. 2018; 4: eaas8772.

[110]

Zhang P, Tong X, Gao Y, et al. A sensing and stretchable polymer-dispersed liquid crystal device based on spiderweb-inspired silver nanowires-micromesh transparent electrode. Adv Funct Mater. 2023; 33: 2303270.

[111]

Guo CF, Sun T, Liu Q, et al. Highly stretchable and transparent nanomesh electrodes made by grain boundary lithography. Nat Commun. 2014; 5: 3121.

[112]

Moon S, Park HK, Song JH, et al. Metal deposition on a self-generated microfibril network to fabricate stretchable tactile sensors providing analog position information. Adv Mater. 2018; 30: 1801408.

[113]

Fang Y, Li Y, Wang X, et al. Cryo-transferred ultrathin and stretchable epidermal electrodes. Small. 2020; 16: 2000450.

[114]

Tian K, Chen C, Xiong L, et al. Fast-crosslinking enabled self-roughed polydimethylsiloxane transparent superhydrophobic coating and its application in anti-liquid-interference electrothermal device. Small. 2023:2308051.

[115]

Kim BS, Pyo JB, Son JG, et al. Biaxial stretchability and transparency of Ag nanowire 2D mass-spring networks prepared by floating compression. ACS Appl Mater Interfaces. 2017; 9: 10865-10873.

[116]

Pyo JB, Kim BS, Park H, et al. Floating compression of Ag nanowire networks for effective strain release of stretchable transparent electrodes. Nanoscale. 2015; 7: 16434-16441.

[117]

Lee S, Sasaki D, Kim D, et al. Ultrasoft electronics to monitor dynamically pulsing cardiomyocytes. Nat Nanotechnol. 2019; 14: 156-160.

[118]

Lee P, Lee J, Lee H, et al. Highly stretchable and highly conductive metal electrode by very long metal nanowire percolation network. Adv Mater. 2012; 24: 3326-3332.

[119]

Kang H, Yi G-R, Kim YJ, et al. Junction welding techniques for metal nanowire network electrodes. Macromol Res. 2018; 26: 1066-1073.

[120]

Son D, Kang J, Vardoulis O, et al. An integrated self-healable electronic skin system fabricated via dynamic reconstruction of a nanostructured conducting network. Nat Nanotechnol. 2018; 13: 1057-1065.

[121]

Xiong J, Li S, Ciou J-H, et al. A tailorable spray-assembly strategy of silver nanowires-bundle mesh for transferable high-performance transparent conductor. Adv Funct Mater. 2021; 31: 2006120.

[122]

Rattfaelt L, Linden M, Hult P, et al. Electrical characteristics of conductive yarns and textile electrodes for medical applications. Med Biol Eng Comput. 2007; 45: 1251-1257.

[123]

Shi X, Zuo Y, Zhai P, et al. Large-area display textiles integrated with functional systems. Nature. 2021; 591: 240-245.

[124]

Shi X, Chen P, Peng H. Making large-scale, functional, electronic textiles. Nature. Forthcoming 2021.

[125]

Sim K, Gao Y, Chen Z, et al. Nylon fabric enabled tough and flaw insensitive stretchable electronics. Adv Mater Technol. 2019; 4: 1800466.

[126]

Liu ZF, Fang S, Moura FA, et al. Hierarchically buckled sheath-core fibers for superelastic electronics, sensors, and muscles. Science. 2015; 349: 400-404.

[127]

Zhao Z, Huang Q, Yan C, et al. Machine-washable and breathable pressure sensors based on triboelectric nanogenerators enabled by textile technologies. Nano Energy. 2020; 70: 104528.

[128]

de Medeiros MS, Chanci D, Moreno C. Waterproof, breathable, and antibacterial self-powered e-textiles based on omniphobic triboelectric nanogenerators. Adv Funct Mater. 2019; 29: 1904350.

[129]

Karim N, Afroj S, Tan S, et al. Scalable production of graphene-based wearable E-textiles. ACS Nano. 2017; 11: 12266-12275.

[130]

Sadi MS, Pan J, Xu A, et al. Direct dip-coating of carbon nanotubes onto polydopamine-templated cotton fabrics for wearable applications. Cellulose. 2019; 26: 7569-7579.

[131]

Manjakkal L, Pullanchiyodan A, Yogeswaran N, et al. A wearable supercapacitor based on conductive PEDOT:PSS-coated cloth and a sweat electrolyte. Adv Mater. 2020; 32: 1907254.

[132]

Wu Y, Mechael SS, Chen Y, et al. Solution deposition of conformal gold coatings on knitted fabric for E-textiles and electroluminescent clothing. Adv Mater Technol. 2018; 3: 1700292.

[133]

Wang Y, Yokota T, Someya T. Electrospun nanofiber-based soft electronics. NPG Asia Mater. 2021; 13: 22.

[134]

Al-Abduljabbar A, Farooq I. Electrospun polymer nanofibers: processing, properties, and applications. Polymers. 2023; 15: 65.

[135]

Jiang Z, Nayeem MOG, Fukuda K, et al. Highly stretchable metallic nanowire networks reinforced by the underlying randomly distributed elastic polymer nanofibers via interfacial adhesion improvement. Adv Mater. 2019; 31: 1903446.

[136]

Wang Y, Lee S, Wang H, et al. Robust, self-adhesive, reinforced polymeric nanofilms enabling gas-permeable dry electrodes for long-term application. PNAS. 2021; 118: e2111904118.

[137]

Chen F, Zhuang Q, Ding Y, et al. Wet-adaptive electronic skin. Adv Mater. 2023; 35: 2305630.

[138]

Wang C, Wang C, Huang Z, et al. Materials and structures toward soft electronics. Adv Mater. 2018; 30: 1801368.

[139]

Yan S, Zhang G, Jiang H, et al. Highly stretchable room-temperature self-healing conductors based on wrinkled graphene films for flexible electronics. ACS Appl Mater Interfaces. 2019; 11: 10736-10744.

[140]

Yoon K, Lee S, Shim D, et al. Strain-insensitive stretchable fiber conductors based on highly conductive buckled shells for wearable electronics. ACS Appl Mater Interfaces. 2023; 15: 18281-18289.

[141]

Weng W, Sun Q, Zhang Y, et al. A gum-like lithium-ion battery based on a novel arched structure. Adv Mater. 2015; 27: 1363-1369.

[142]

Chen G, Matsuhisa N, Liu Z, et al. Plasticizing silk protein for on-skin stretchable electrodes. Adv Mater. 2018; 30: 1800129.

[143]

Zhao L, Yu S, Li J, et al. Spontaneously-buckled microstructure of copper nanowire conductors for a highly stretchable heater. J Mater Chem C. 2021; 9: 13886-13895.

[144]

Liang F-C, Chang Y-W, Kuo C-C. et al. A mechanically robust silver nanowire-polydimethylsiloxane electrode based on facile transfer printing techniques for wearable displays. Nanoscale. 2019; 11: 1520-1530.

[145]

Silva CA, lv J, Yin L, et al. Liquid metal based island-bridge architectures for all printed stretchable electrochemical devices. Adv Funct Mater. 2020; 30: 2002041.

[146]

Park HJ, Jeong J-M, Son SG, et al. Fluid-dynamics-processed highly stretchable, conductive, and printable graphene inks for real-time monitoring sweat during stretching exercise. Adv Funct Mater. 2021; 31: 2011059.

[147]

Yuan H, Jia R, Yao H, et al. Ultra-stable, waterproof and self-healing serpentine stretchable conductors based on WPU sheath-wrapped conductive yarn for stretchable interconnects and wearable heaters. Chem Eng J. 2023; 473: 145251.

[148]

Li Z, Song J, Hu H, et al. Rolled-up island-bridge (RIB): a new and general electrode configuration design for a wire-shaped stretchable micro-supercapacitor array. J Mater Chem A. 2021; 9: 2899-2911.

[149]

Jiang C, Li Q, Fan S, et al. Hyaline and stretchable haptic interfaces based on serpentine-shaped silver nanofiber networks. Nano Energy. 2020; 73: 104782.

[150]

Yang JC, Lee S, Ma BS, et al. Geometrically engineered rigid island array for stretchable electronics capable of withstanding various deformation modes. Sci Adv. 2022; 8: eabn3863.

[151]

Jang S, Kim C, Park JJ, et al. A high aspect ratio serpentine structure for use as a strain-insensitive, stretchable transparent conductor. Small. 2018; 14: 1702818.

[152]

Yin L, Seo JK, Kurniawan J, et al. Highly stable battery pack via insulated, reinforced, buckling-enabled interconnec. array. Small. 2018; 14: 1800938.

[153]

Ma R, Wu C, Wang ZL, et al. Pop-up conducting large-area biographene kirigami. ACS Nano. 2018; 12: 9714-9720.

[154]

Li X, Zhu P, Zhang S, et al. A self-supporting, conductor-exposing, stretchable, ultrathin, and recyclable kirigami-structured liquid metal paper for multifunctional E-skin. ACS Nano. 2022; 16: 5909-5919.

[155]

Hartmann F, Jakešová M, Mao G, et al. Scalable microfabrication of folded parylene-based conductors for stretchable electronics. Adv Electron Mater. 2021; 7: 2001236.

[156]

Kim J, Park H, Jeong S-H. A kirigami concept for transparent and stretchable nanofiber networks-based conductors and UV photodetectors. J Ind Eng Chem. 2020; 82: 144-152.

[157]

Okogbue E, Han SS, Ko T-J, et al. Multifunctional two-dimensional PtSe₂-layer kirigami conductors with 2000% stretchability and metallic-to-semiconducting tunability. Nano Lett. 2019; 19(11): 7598-7607.

[158]

Weng C, Dai Z, Wang G, et al. Elastomer-free, stretchable, and conformable silver nanowire conductors enabled by three-dimensional buckled microstructures. ACS Appl Mater Interfaces. 2019; 11: 6541-6549.

[159]

Gao Y, Guo F, Cao P, et al. Winding-locked carbon nanotubes/polymer nanofibers helical yarn for ultrastretchable conductor and strain sensor. ACS Nano. 2020; 14: 3442-3450.

[160]

Woo J, Lee H, Yi C, et al. Ultrastretchable helical conductive fibers using percolated ag nanoparticle networks encapsulated by elastic polymers with high durability in omnidirectional deformations for wearable electronics. Adv Funct Mater. 2020; 30: 1910026.

[161]

Li Q, Ding C, Yuan W, et al. Highly stretchable and permeable conductors based on shrinkable electrospun fiber mats. Adv Fiber Mater. 2021; 3: 302-311.

[162]

Gao F, Zhang Z, Zhao X, et al. Highly conductive and stretching-insensitive films for wearable accurate pressure perception. Chem Eng J. 2022; 429: 132488.

[163]

Lee HM, Kim MH, Jin Y, et al. Hierarchically engineered unibody Au mesh for stretchable and transparent conductors. J Mater Chem A. 2023; 11: 4220-4229.

[164]

Son W, Chun S, Lee JM, et al. Highly twisted supercoils for superelastic multi-functional fibres. Nat Commun. 2019; 10: 426.

[165]

Ma Z, Huang Q, Xu Q, et al. Permeable superelastic liquid-metal fibre mat enables biocompatible and monolithic stretchable electronics. Nat Mater. 2021; 20: 859-868.

[166]

Yu C, Masarapu C, Rong J, et al. Stretchable supercapacitors based on buckled single-walled carbon-nanotube macrofilms. Adv Mater. 2009; 21: 4793-4797.

[167]

Wang B, Bao S, Vinnikova S, et al. Buckling analysis in stretchable electronics. npj Flexible Electron. 2017; 1: 5.

[168]

Kaltenbrunner M, Sekitani T, Reeder J, et al. An ultra-lightweight design for imperceptible plastic electronics. Nature. 2013; 499: 458-463.

[169]

Dai Y, Hu H, Wang M, et al. Stretchable transistors and functional circuits for human-integrated electronics. Nat Electron. 2021; 4: 17-29.

[170]

Chen J, Huang W, Zheng D, et al. Highly stretchable organic electrochemical transistors with strain-resistant performance. Nat Mater. 2022; 21: 564-571.

[171]

Zeng S, Zhang D, Huang W, et al. Bio-inspired sensitive and reversible mechanochromisms via strain-dependent cracks and folds. Nat Commun. 2016; 7: 11802.

[172]

Huang Y, Zhong M, Huang Y, et al. A self-healable and highly stretchable supercapacitor based on a dual crosslinked polyelectrolyte. Nat Commun. 2015; 6: 10310.

[173]

Wirthl D, Pichler R, Drack M, et al. Instant tough bonding of hydrogels for soft machines and electronics. Sci Adv. 2017; 3: e1700053.

[174]

Drack M, Graz I, Sekitani T, et al. An imperceptible plastic electronic wrap. Adv Mater. 2015; 27: 34-40.

[175]

Zang J, Ryu S, Pugno N, et al. Multifunctionality and control of the crumpling and unfolding of large-area graphene. Nat Mater. 2013; 12: 321-325.

[176]

Zang J, Cao C, Feng Y, et al. Stretchable and high-performance supercapacitors with crumpled graphene papers. Sci Rep. 2014; 4: 6492.

[177]

Cao C, Zhou Y, Ubnoske S, et al. Highly stretchable supercapacitors via crumpled vertically aligned carbon nanotube forests. Adv Energy Mater. 2019; 9: 1900618.

[178]

Jin Y, Hwang S, Ha H, et al. Buckled Au@PVP nanofiber networks for highly transparent and stretchable conductors. Adv Electron Mater. 2016; 2: 1500302.

[179]

Xie Y, Liu Y, Zhao Y, et al. Stretchable all-solid-state supercapacitor with wavy shaped polyaniline/graphene electrode. J Mater Chem A. 2014; 2: 9142-9149.

[180]

Kim BS, Kwon H, Kwon HJ, et al. Buckling instability control of 1D nanowire networks for a large-area stretchable and transparent electrode. Adv Funct Mater. 2020; 30: 1910214.

[181]

Fan JA, Yeo W-H, Su Y, et al. Fractal design concepts for stretchable electronics. Nat Commun. 2014; 5: 3266.

[182]

Zhang Y, Xu S, Fu H, et al. Buckling in serpentine microstructures and applications in elastomer-supported ultra-stretchable electronics with high areal coverage. Soft Matter. 2013; 9: 8062-8070.

[183]

Yan Z, Pan T, Wang D, et al. Stretchable micromotion sensor with enhanced sensitivity using serpentine layout. ACS Appl Mater Interfaces. 2019; 11: 12261-12271.

[184]

Kim HW, Kim TY, Park HK, et al. Hygroscopic auxetic on-skin sensors for easy-to-handle repeated daily use. ACS Appl Mater Interfaces. 2018; 10: 40141-40148.

[185]

Bandodkar AJ, You J-M, Kim N-H. et al. Soft, stretchable, high power density electronic skin-based biofuel cells for scavenging energy from human sweat. Energy Environ Sci. 2017; 10: 1581-1589.

[186]

Mohan AMV, Kim N, Gu Y, et al. Merging of thin-and thick-film fabrication technologies: toward soft stretchable “island-bridge” devices. Adv Mater Technol. 2017; 2(4):1600284.

[187]

Kim D-H, Lu N, Ma R, et al. Epidermal electronics. Science. 2011; 333: 838-843.

[188]

Xu S, Zhang Y, Jia L, et al. Soft microfluidic assemblies of sensors, circuits, and radios for the skin. Science. 2014; 344: 70-74.

[189]

Choi S, Park J, Hyun W, et al. Stretchable heater using ligand-exchanged silver nanowire nanocomposite for wearable articular thermotherapy. ACS Nano. 2015; 9: 6626-6633.

[190]

Plovie B, Yang Y, Guillaume J, et al. Arbitrarily shaped 2.5D circuits using stretchable interconnects embedded in thermoplastic polymers. Adv Eng Mater. 2017; 19: 1700032.

[191]

Kim D, Shin G, Kang YJ, et al. Fabrication of a stretchable solid-state micro-supercapacitor array. ACS Nano. 2013; 7: 7975-7982.

[192]

Zhao J, Hu H, Fang W, et al. Liquid-metal-bridge˜island design: seamless integration of intrinsically stretchable liquid metal circuits and mechanically deformable structures for ultra-stretchable all-solid-state rechargeable Zn-air battery arrays. J Mater Chem A. 2021; 9: 5097-5110.

[193]

Yang S, Su B, Bitar G, et al. Stretchability of indium tin oxide (ITO) serpentine thin films supported by Kapton substrates. Int J Fract. 2014; 190: 99-110.

[194]

Xu S, Zhang Y, Cho J, et al. Stretchable batteries with self-similar serpentine interconnects and integrated wireless recharging systems. Nat Commun. 2013; 4: 1543.

[195]

Yan Z, Liu Y, Xiong J, et al. Hierarchical serpentine-helix combination for 3D stretchable electronics. Adv Mater. 2023; 35: 2210238.

[196]

Zhang Y, Wang S, Li X, et al. Experimental and theoretical studies of serpentine microstructures bonded to prestrained elastomers for stretchable electronics. Adv Funct Mater. 2014; 24: 2028-2037.

[197]

Pan T, Pharr M, Ma Y, et al. Experimental and theoretical studies of serpentine interconnects on ultrathin elastomers for stretchable electronics. Adv Funct Mater. 2017; 27: 1702589.

[198]

Li K, Shuai Y, Cheng X, et al. Island effect in stretchable inorganic electronics. Small. 2022; 18: 2107879.

[199]

Song J, Huang Y, Xiao J, et al. Mechanics of noncoplanar mesh design for stretchable electronic circuits. J Appl Phys. 2009; 105: 123516.

[200]

Xu L, Shyu TC, Kotov NA. Origami and kirigami nanocomposites. ACS Nano. 2017; 11: 7587-7599.

[201]

Callens SJP, Zadpoor AA. From flat sheets to curved geometries: origami and kirigami approaches. Mater Today. 2018; 21: 241-264.

[202]

Li Y, Zhang Q, Hong Y, et al. 3D transformable modular kirigami based programmable metamaterials. Adv Funct Mater. 2021; 31: 2105641.

[203]

Dieleman P, Vasmel N, Waitukaitis S, et al. Jigsaw puzzle design of pluripotent origami. Nat Phys. 2020; 16: 63-68.

[204]

Hong Y, Chi Y, Wu S, et al. Boundary curvature guided programmable shape-morphing kirigami sheets. Nat Commun. 2022; 13: 530.

[205]

Jamalimehr A, Mirzajanzadeh M, Akbarzadeh A, et al. Rigidly flat-foldable class of lockable origami-inspired metamaterials with topological stiff states. Nat Commun. 2022; 13: 1816.

[206]

Walker A, Stankovic T. Algorithmic design of origami mechanisms and tessellations. Commun Mater. 2022; 3: 4.

[207]

Dudte LH, Choi GPT, Becker KP, et al. An additive framework for kirigami design. Nat Comput Sci. 2023; 3: 443-454.

[208]

Morikawa Y, Yamagiwa S, Sawahata H, et al. Ultrastretchable kirigami bioprobes. Adv Healthcare Mater. 2018; 7: 1701100.

[209]

Babaee S, Shi Y, Abbasalizadeh S, et al. Kirigami-inspired stents for sustained local delivery of therapeutics. Nat Mater. 2021; 20: 1085-1092.

[210]

Rafsanjani A, Zhang Y, Liu B, et al. Kirigami skins make a simple soft actuator crawl. Sci Rob. 2018; 3: eaar7555.

[211]

Kim W, Byun J, Kim J-K, et al. Bioinspired dual-morphing stretchable origami. Sci Rob. 2019; 4: eaay3493.

[212]

Yang Y, Vella K, Holmes DP. Grasping with kirigami shells. Sci Rob. 2021; 6: eabd6426.

[213]

Yang P-K, Lin Z-H, Pradel KC, et al. Paper-based origami triboelectric nanogenerators and self-powered pressure sensors. ACS Nano. 2015; 9: 901-907.

[214]

Wu C, Wang X, Lin L, et al. Paper-based triboelectric nanogenerators made of stretchable interlocking kirigami patterns. ACS Nano. 2016; 10: 4652-4659.

[215]

Chen S, Chen J, Zhang X, et al. Kirigami/origami: unfolding the new regime of advanced 3D microfabrication/nanofabrication with “folding”. Light Sci Appl. 2020; 9: 75.

[216]

Zhang Z, Tian Z, Mei Y, et al. Shaping and structuring 2D materials via kirigami and origami. Mater Sci Eng R Rep. 2021; 145: 100621.

[217]

Cui J, Poblete FR, Zhu Y. Origami/kirigami-guided morphing of composite sheets. Adv Funct Mater. 2018; 28: 1802768.

[218]

Blees MK, Barnard AW, Rose PA, et al. Graphene kirigami. Nature. 2015; 524: 204-207.

[219]

Shyu TC, Damasceno PF, Dodd PM, et al. A kirigami approach to engineering elasticity in nanocomposites through patterned defects. Nat Mater. 2015; 14: 785-789.

[220]

Wang Z, Zhang L, Duan S, et al. Kirigami-patterned highly stretchable conductors from flexible carbon nanotube-embedded polymer films. J Mater Chem C. 2017; 5: 8714-8722.

[221]

Yiming B, Wu L, Zhang M, et al. Highly stretchable bilayer lattice structures that elongate via in-plane deformation. Adv Funct Mater. 2020; 30: 1909473.

[222]

Lu Z, Deng Y, Zhou X, et al. Highly stretchable conductor inspired by compliant mechanism. Adv Electron Mater. 2023; 9: 2300343.

[223]

Oyefusi A, Chen J. Reprogrammable chemical 3D shaping for origami, kirigami, and reconfigurable molding. Angew Chem Int Edit. 2017; 56: 8250-8253.

[224]

Tang Y, Lin G, Yang S, et al. Programmable kiri-kirigami metamaterials. Adv Mater. 2017; 29: 1604262.

[225]

Choi GPT, Dudte LH, Mahadevan L. Programming shape using kirigami tessellations. Nat Mater. 2019; 18: 999-1004.

[226]

Jin L, Yeager M, Lee Y-J, et al. Shape-morphing into 3D curved surfaces with nacre-like composite architectures. Sci Adv. 2022; 8: eabq3248.

[227]

Zhang H, Paik J. Kirigami design and modeling for strong, lightweight metamaterials. Adv Funct Mater. 2022; 32: 2107401.

[228]

Ye H, Liu Q, Cheng J, et al. Multimaterial 3D printed self-locking thick-panel origami metamaterials. Nat Commun. 2023; 14: 1607.

[229]

Shang Y, Li Y, He X, et al. Elastic carbon nanotube straight yarns embedded with helical loops. Nanoscale. 2013; 5: 2403-2410.

[230]

Zhang Y, Bai W, Cheng X, et al. Flexible and stretchable lithium-ion batteries and supercapacitors based on electrically conducting carbon nanotube fiber springs. Angew Chem Int Edit. 2014; 53: 14564-14568.

[231]

Chen P, Xu Y, He S, et al. Hierarchically arranged helical fibre actuators driven by solvents and vapours. Nat Nanotechnol. 2015; 10: 1077-1083.

[232]

Li H, Liu Z, Liang G, et al. Waterproof and tailorable elastic rechargeable yarn zinc ion batteries by a cross-linked polyacrylamide electrolyte. ACS Nano. 2018; 12: 3140-3148.

[233]

Yang Z, Zhai Z, Song Z, et al. Conductive and elastic 3D helical fibers for use in washable and wearable electronics. Adv Mater. 2020; 32: 1907495.

[234]

Zhang C, Zhang L, Pu Z, et al. Fabricating 1D stretchable fiber-shaped electronics based on inkjet printing technology for wearable applications. Nano Energy. 2023; 113: 108574.

[235]

Yun MJ, Sim YH, Lee DY, et al. Highly stretchable large area woven, knitted and robust braided textile based interconnection for stretchable electronics. Sci Rep. 2021; 11: 4038.

[236]

Wu Y, Tang H, Wang L, et al. Temperature-insensitive stretchable conductors based on hierarchical double-layer graphene foams/PEDOT:PSS networks. Compos Sci Technol. 2023; 242: 110190.

[237]

Wang C, Zhang M, Xia K, et al. Intrinsically stretchable and conductive textile by a scalable process for elastic wearable electronics. ACS Appl Mater Interfaces. 2017; 9: 13331-13338.

[238]

Ding Y, Xu W, Wang W, et al. Scalable and facile preparation of highly stretchable electrospun PEDOT:PSS@PU fibrous nonwovens toward wearable conductive textile applications. ACS Appl Mater Interfaces. 2017; 9: 30014-30023.

[239]

Ma X, Zhang M, Zhang J, et al. Highly permeable and ultrastretchable liquid metal micromesh for skin-attachable electronics. ACS Mater Lett. 2022; 4: 634-641.

[240]

Sun Y, Lopez J, Lee H-W, et al. A stretchable graphitic carbon/Si anode enabled by conformal coating of a self-healing elastic polymer. Adv Mater. 2016; 28: 2455-2461.

[241]

Liu W, Chen Z, Zhou G, et al. 3D porous sponge-inspired electrode for stretchable lithium-ion batteries. Adv Mater. 2016; 28: 3578-3583.

[242]

Li H, Ding Y, Ha H, et al. An all-stretchable-component sodium-ion full battery. Adv Mater. 2017; 29: 1700898.

[243]

Peng X, Dong K, Ye C, et al. A breathable, biodegradable, antibacterial, and self-powere. electronic skin based on all-nanofiber triboelectric nanogenerators. Sci Adv. 2020; 6: eaba9624.

[244]

Ibrahim ID, Jamiru T, Sadiku ER, et al. Application of nanoparticles and composite materials for energy generation and storage. IET Nanodielectr. 2019; 2: 115-122.

[245]

Zhang J-W, Meng X, Han T, et al. Optical magnetic field sensors based on nanodielectrics: from biomedicine to IoT-based energy internet. IET Nanodielectr. 2023; 6: 116-129.

[246]

He X, Shi J, Hao Y, et al. PEDOT:PSS/CNT composites based ultra-stretchable thermoelectrics and their application as strain sensors. Compos Commun. 2021; 27: 100822.

[247]

Pu X, Zhang C, Wang ZL. Triboelectric nanogenerators as wearable power sources and self-powered sensors. Natl Sci Rev. 2023; 10: nwac170.

[248]

Chen C, Wang M, Chen X, et al. Recent progress in solar photothermal steam technology for water purification and energy utilization. Chem Eng J. 2022; 448: 137603.

[249]

Hu W-w, Shi X-y, Gao M-h. et al. Light-actuated shape memory and self-healing phase change composites supported by MXene/waterborne polyurethane aerogel for superior solar-thermal energy storage. Compos Commun. 2021; 28: 100980.

[250]

Liu Z, Li H, Shi B, et al. Wearable and implantable triboelectric nanogenerators. Adv Funct Mater. 2019; 29: 1808820.

[251]

Hao Y, He X, Wang L, et al. Stretchable thermoelectrics: strategies, performances, and applications. Adv Funct Mater. 2022; 32: 2109790.

[252]

Kim JY, Lee J-W, Jung HS, et al. High-efficiency perovskite solar cells. Chem Rev. 2020; 120: 7867-7918.

[253]

Cai Q, Zhao D, Xu H, et al. Crosslinked PAES-based sandwich-structured polymer nanocomposites with covalently strengthened interface towards high-temperature capacitive energy storage. Nanocomposites. 2023; 9: 10-17.

[254]

Aazem I, Mathew DT, Radhakrishnan S, et al. Electrode materials for stretchable triboelectric nanogenerator in wearable electronics. RSC Adv. 2022; 12: 10545-10572.

[255]

Wang ZL, Chen J, Lin L. Progress in triboelectric nanogenerators as a new energy technology and self-powered sensors. Energy Environ Sci. 2015; 8: 2250-2282.

[256]

Jin DW, Ko YJ, Ahn CW, et al. Polarization-and electrode-optimized polyvinylidene fluoride films for harsh environmental piezoelectric nanogenerator applications. Small. 2021; 17: 2007289.

[257]

Wu C, Wang AC, Ding W, et al. Triboelectric nanogenerator: a foundation of the energy for the new era. Adv Energy Mater. 2019; 9: 1802906.

[258]

Yang Y, Sun N, Wen Z, et al. Liquid-metal-based super-stretchable and structure-designable triboelectric nanogenerator for wearable electronics. ACS Nano. 2018; 12: 2027-2034.

[259]

Yang Y, Han J, Huang J, et al. Stretchable energy-harvesting tactile interactive interface with liquid-metal-nanoparticle-based electrodes. Adv Funct Mater. 2020; 30: 1909652.

[260]

Park MK, Lee S, Ko Y, et al. A cerebral cortex-like structured metallized elastomer for high-performance triboelectric nanogenerator. Nano Energy. 2023; 116: 108828.

[261]

He J, Zhou R, Zhang Y, et al. Strain-insensitive self-powered tactile sensor arrays based on intrinsically stretchable and patternable ultrathin conformal wrinkled graphene-elastomer composite. Adv Funct Mater. 2022; 32: 2107281.

[262]

Kang H, Zhao C, Huang J, et al. Fingerprint-inspired conducting hierarchical wrinkles for energy-harvesting E-Skin. Adv Funct Mater. 2019; 29: 1903580.

[263]

Chen H, Xu Y, Bai L, et al. Crumpled graphene triboelectric nanogenerators: smaller devices with higher output performance. Adv Mater Technol. 2017; 2: 1700044.

[264]

Wang H, Rao Z, Liu Y, et al. A highly stretchable triboelectric nanogenerator with both stretch-insensitive sensing and stretch-sensitive sensing. Nano Energy. 2023; 107: 108170.

[265]

Kim S, Gupta MK, Lee KY, et al. Transparent flexible graphene triboelectric nanogenerators. Adv Mater. 2014; 26: 3918-3925.

[266]

Wang X, Zhang Y, Zhang X, et al. A highly stretchable transparent self-powered triboelectric tactile sensor with metallized nanofibers for wearable electronics. Adv Mater. 2018; 30: 1706738.

[267]

Sim HJ, Choi C, Lee CJ, et al. Flexible, stretchable and weavable piezoelectric fiber. Adv Eng Mater. 2015; 17: 1270-1275.

[268]

Qian S, Qin L, He J, et al. A stretchable piezoelectric elastic composite. Mater Lett. 2019; 236: 96-100.

[269]

Huang X, Qin Q, Wang X, et al. Piezoelectric nanogenerator for highly sensitive and synchronous multi-stimuli sensing. ACS Nano. 2021; 15: 19783-19792.

[270]

Jeong CK, Lee J, Han S, et al. A hyper-stretchable elastic-composite energy harvester. Adv Mater. 2015; 27: 2866-2875.

[271]

Kaur G, Meena JS, Jassal M, et al. Synergistic effect of polyurethane in polyurethane-poly(vinylidene fluoride) nanofiber-based stretchable piezoelectric nanogenerators (S-PENGs). ACS Appl Polym Mater. 2022; 4: 4751-4764.

[272]

Zhou X, Parida K, Halevi O, et al. All 3D-printed stretchable piezoelectric nanogenerator with non-protruding kirigami structure. Nano Energy. 2020; 72: 104676.

[273]

Sun T, Chen S, Sun H, et al. Wavy-structured thermoelectric device integrated with high-performance n-type carbon nanotube fiber prepared by multistep treatment for energy harvesting. Compos Commun. 2021; 27: 100871.

[274]

Xu C, Yang S, Li P, et al. Wet-spun PEDOT:PSS/CNT composite fibers for wearable thermoelectric energy harvesting. Compos Commun. 2022; 32: 101179.

[275]

Hou C, Zhu M. Semiconductors flex thermoelectric power. Science. 2022; 377: 815-816.

[276]

Yang Q, Yang S, Qiu P, et al. Flexible thermoelectrics based on ductile semiconductors. Science. 2022; 377: 854-858.

[277]

Kim N, Lienemann S, Petsagkourakis I, et al. Elastic conducting polymer composites in thermoelectric modules. Nat Commun. 2020; 11: 1424.

[278]

Jang D, Park KT, Lee S-S, et al. Highly stretchable three-dimensional thermoelectric fabrics exploiting woven structure deformability and passivation-induced fiber elasticity. Nano Energy. 2022; 97: 107143.

[279]

Deng S, Dong C, Liu J, et al. An n-type polythiophene derivative with excellent thermoelectric performance. Angew Chem Int Edit. 2023; 62: 2216049.

[280]

Ke Z, Abtahi A, Hwang J, et al. Highly conductive and solution-processable n-doped transparent organic conductor. J Am Chem Soc. 2023; 145: 3706-3715.

[281]

Li Q, Deng M, Zhang S, et al. Synergistic enhancement of thermoelectric and mechanical performances of ionic liquid LiTFSI modulated PEDOT flexible films. J Mater Chem C. 2019; 7(15): 4374-4381.

[282]

Taroni PJ, Santagiuliana G, Wan K, et al. Toward stretchable self-powered sensors based on the thermoelectric response of PEDOT:PSS/polyurethane blends. Adv Funct Mater. 2018; 28: 1704285.

[283]

Zhang D, Song Y, Ping L, et al. Photo-thermoelectric effect induced electricity in stretchable graphene-polymer nanocomposites for ultrasensitive strain sensing. Nano Res. 2019; 12: 2982-2987.

[284]

Zhang D, Zhang K, Wang Y, et al. Thermoelectric effect induced electricity in stretchable graphene-polymer nanocomposites for ultrasensitive self-powered strain sensor system. Nano Energy. 2019; 56: 25-32.

[285]

Cao G, He G, Lu L, et al. Hydrogen-bonded n-type waterborne polyurethane/lysine/single-walled carbon nanotube ternary composite: combining excellent thermoelectric and stretchable properties toward self-powered temperature and strain sensors. Chem Eng J. 2023; 474: 145664.

[286]

Wan K, Taroni PJ, Liu Z, et al. Flexible and stretchable self-powered multi-sensors based on the n-type thermoelectric response of polyurethane/Nax(Ni-ett)n composites. Adv Electron Mater. 2019; 5(12):1900582.

[287]

Kim S, Na Y, Nam C, et al. Highly tailorable, ultra-foldable, and resorbable thermoelectric paper for origami-enabled energy generation. Nano Energy. 2022; 103: 107824.

[288]

Yang Y, Hu H, Chen Z, et al. Stretchable nanolayered thermoelectric energy harvester on complex and dynamic surfaces. Nano Lett. 2020; 20: 4445-4453.

[289]

Jung Y, Choi J, Yoon Y, et al. Soft multi-modal thermoelectric skin for dual functionality of underwater energy harvesting and thermoregulation. Nano Energy. 2022; 95: 107002.

[290]

Li Y, Zeng J, Zhao Y, et al. Fabric-based flexible thermoelectric generators: design methods and prospects. Front Mater. 2022; 9: 1046883.

[291]

Zhang G, Lin FR, Qi F, et al. Renewed prospects for organic photovoltaics. Chem Rev. 2022; 122: 14180-14274.

[292]

Sun K, Li P, Xia Y, et al. Transparent conductive oxide-free perovskite solar cells with PEDOT:PSS as transparent electrode. ACS Appl Mater Interfaces. 2015; 7: 15314-15320.

[293]

Yoon J, Sung H, Lee G, et al. Superflexible, high-efficiency perovskit. solar cells utilizing graphene electrodes: towards future foldable power sources. Energy Environ Sci. 2017; 10: 337-345.

[294]

Anand A, Islam MM, Meitzner R, et al. Introduction of a novel figure of merit for the assessment of transparent conductive electrodes in photovoltaics: exact and approximate form. Adv Energy Mater. 2021; 11: 2100875.

[295]

Gan Y, Sun J, Guo P, et al. Advances in the research of carbon electrodes for perovskite solar cells. Dalton Trans. 2023; 52: 16558-16577.

[296]

Wen R, Huang H, Wan J, et al. High-efficiency stable flexible organic solar cells with PEDOT:PSS electrodes via superacid fumigation treatment. Energy Technol. 2021; 9: 2100595.

[297]

Wan J, Fan X, Li Y, et al. High-efficiency flexible organic photovoltaics and thermoelectricities based on thionyl chloride treated PEDOT:PSS electrodes. Front Chem. 2022; 9: 807538.

[298]

Lee M, Jo Y, Kim DS, et al. Efficient, durable and flexible perovskite photovoltaic devices with Ag-embedded ITO as the top electrode on a metal substrate. J Mater Chem A. 2015; 3: 14592-14597.

[299]

Vaagensmith B, Reza KM, Hasan MDN, et al. Environmentally friendly plasma-treated PEDOT:PSS as electrodes for ITO-Free perovskite solar cells. ACS Appl Mater Interfaces. 2017; 9: 35861-35870.

[300]

Mabrouk S, Gurung A, Bahrami B, et al. Electrochemically prepared polyaniline as an alternative to poly(3, 4-ethylenedioxythiophene)-poly(styrenesulfonate) for inverted perovskite solar cells. ACS Appl Energy Mater. 2022; 5: 9351-9360.

[301]

Zamarayeva AM, Ostfeld AE, Wang M, et al. Flexible and stretchable power sources for wearable electronics. Sci Adv. 2017; 3: e1602051.

[302]

Wu Y, Mechael SS, Chen Y, et al. Velour fabric as an island-bridge architectural design for stretchable textile-based lithium-ion battery electrodes. ACS Appl Mater Interfaces. 2020; 12: 51679-51687.

[303]

Qu S, Song Z, Liu J, et al. Electrochemical approach to prepare integrated air electrodes for highly stretchable zinc-air battery array with tunable output voltage and current for wearable electronics. Nano Energy. 2017; 39: 101-110.

[304]

Song Z, Ma T, Tang R, et al. Origami lithium-ion batteries. Nat Commun. 2014; 5: 3140.

[305]

Nasreldin M, Delattre R, Calmes C, et al. High performance stretchable Li-ion microbattery. Energy Storage Mater. 2020; 33: 108-115.

[306]

Bao Y, Liu Y, Kuang Y, et al. 3D-printed highly deformable electrodes for flexible lithium ion batteries. Energy Storage Mater. 2020; 33: 55-61.

[307]

Qian J, Chen Q, Hong M, et al. Toward stretchable batteries: 3D-printed deformable electrodes and separator enabled by nanocellulose. Mater Today. 2022; 54: 18-26.

[308]

Sánchez-Sánchez A, Fierro V, Izquierdo MT, et al. Functionalized, hierarchical and ordered mesoporous carbons for high-performance supercapacitors. J Mater Chem A. 2016; 4: 6140-6148.

[309]

Liu B, Zhang Q, Zhang L, et al. Electrochemically exfoliated chlorine-doped graphene for flexible all-solid-state micro-supercapacitors with high volumetric energy density. Adv Mater. 2022; 34: 2106309.

[310]

Yu H, Kim J-G, Lee D-M. et al. Active material-free continuous carbon nanotube fibers with unprecedented enhancement of physicochemical properties for fiber-type solid-state supercapacitors. Adv Energy Mater. 2023; 14: 2303003.

[311]

Shao Y, El-Kady MF. Sun J, et al. Design and mechanisms of asymmetric supercapacitors. Chem Rev. 2018; 118: 9233-9280.

[312]

Huang Z-H, Song Y, Feng D-Y, et al. High mass loading MnO₂ with hierarchical nanostructures for supercapacitors. ACS Nano. 2018; 12: 3557-3567.

[313]

Lang X, Hirata A, Fujita T, et al. Nanoporous metal/oxide hybrid electrodes for electrochemical supercapacitors. Nat Nanotechnol. 2011; 6: 232-236.

[314]

Brousse K, Pinaud S, Nguyen S, et al. Facile and scalable preparation of ruthenium oxide-based flexible micro-supercapacitors. Adv Energy Mater. 2020; 10: 1903136.

[315]

Karatum O, Yildiz E, Kaleli HN, et al. RuO₂ supercapacitor enables flexible, safe, and efficient optoelectronic neural interface. Adv Funct Mater. 2022; 32: 2109365.

[316]

Nie G, Zhang Z, Liu Y, et al. One-pot rational deposition of coaxial double-layer MnO₂/Ni(OH)₂ nanosheets on carbon nanofibers for high-performance supercapacitors. Adv Fiber Mater. 2022; 4: 1129-1140.

[317]

Kang J, Xue Y, Yang J, et al. Realizing two-electron transfer in Ni(OH)₂ nanosheets for energy storage. J Am Chem Soc. 2022; 144: 8969-8976.

[318]

Jiang Q, Kurra N, Alhabeb M, et al. All pseudocapacitive MXene-RuO₂ asymmetric supercapacitors. Adv Energy Mater. 2018; 8: 1703043.

[319]

Spurling D, Krüger H, Kohlmann N, et al. 3D networked MXene thin films for high performance supercapacitors. Energy Storage Mater. 2023:103148.

[320]

Mateen A, Ansari MZ, Hussain I, et al. Ti₂CT_x-MXene aerogel based ultra-stable Zn-ion supercapacitor. Compos Commun. 2023; 38: 101493.

[321]

He W, Qiang H, Liang S, et al. Hierarchically porous wood aerogel/polypyrrole(PPy) composite thick electrode for supercapacitor. Chem Eng J. 2022; 446: 137331.

[322]

Lan L, Li Y, Zhu J, et al. Highly flexible polypyrrole electrode with acanthosphere-like structures for energy storage and actuator applications. Chem Eng J. 2023; 455: 140675.

[323]

Wang Y, Chu X, Zhu Z, et al. Dynamically evolving 2D supramolecular polyaniline nanosheets for long-stability flexible supercapacitors. Chem Eng J. 2021; 423: 130203.

[324]

Chen Q, Wang X, Chen F, et al. Extremely strong and tough polythiophene composite for flexible electronics. Chem Eng J. 2019; 368: 933-940.

[325]

Anothumakkool B, Soni R, Bhange SN, et al. Novel scalable synthesis of highly conducting and robust PEDOT paper for a high performance flexible solid supercapacitor. Energy Environ Sci. 2015; 8: 1339-1347.

[326]

Kolathodi MS, Akbarinejad A, Tollemache C, et al. Highly stretchable and flexible supercapacitors based on electrospun PEDOT:SSEBS electrodes. J Mater Chem A. 2022; 10: 21124-21134.

[327]

Lv Z, Tang Y, Zhu Z, et al. Honeycomb-lantern-inspired 3D stretchable supercapacitors with enhanced specific areal capacitance. Adv Mater. 2018; 30: 1805468.

[328]

Shao G, Yu R, Zhang X, et al. Making stretchable hybrid supercapacitors by knitting non-stretchable metal fibers. Adv Funct Mater. 2020; 30: 2003153.

[329]

Nam I, Kim G-P, Park S, et al. All-solid-state, origami-type foldabl. supercapacitor chips with integrated series circuit analogues. Energy Environ Sci. 2014; 7: 1095-1102.

[330]

He S, Cao J, Xie S, et al. Stretchable supercapacitor based on a cellular structure. J Mater Chem A. 2016; 4: 10124-10129.

[331]

Zhang R, Ding J, Liu C, et al. Highly stretchable supercapacitors enabled by interwoven CNTs partially embedded in PDMS. ACS Appl Energy Mater. 2018; 1: 2048-2055.

[332]

Mu H, Huang X, Wang W, et al. High-performance-integrated stretchable supercapacitors based on a polyurethane organo/hydrogel electrolyte. ACS Appl Mater Interfaces. 2022; 14: 622-632.

[333]

Lu B, Yuk H, Lin S, et al. Pure PEDOT:PSS hydrogels. Nat Commun. 2019; 10: 1043.

[334]

Li J, Yan W, Zhang G, et al. Natively stretchable micro-supercapacitors based on a PEDOT:PSS hydrogel. J Mater Chem C. 2021; 9: 1685-1692.

[335]

Yu X, Su X, Yan K, et al. Stretchable, conductive, and stable PEDOT-modified textiles through a novel in situ polymerization process for stretchable supercapacitors. Adv Mater Technol. 2016; 1: 1600009.

[336]

Lv Z, Luo Y, Tang Y, et al. Editable supercapacitors with customizable stretchability based on mechanically strengthened ultralong MnO₂ nanowire composite. Adv Mater. 2018; 30: 1704531.

[337]

Gao J, Shao C, Shao S, et al. Laser-assisted multiscale fabrication of configuration-editable supercapacitors with high energy density. ACS Nano. 2019; 13: 7463-7470.

[338]

Wang M, Feng S, Bai C, et al. Ultrastretchable MXene microsupercapacitors. Small. 2023; 19: 2300386.

[339]

Yang J, Cao Q, Tang X, et al. 3D-Printed highly stretchable conducting polymer electrodes for flexible supercapacitors. J Mater Chem A. 2021; 9: 19649-19658.

[340]

Ortaboy S, Alper JP, Rossi F, et al. MnO_x-decorated carbonized porous silicon nanowire electrodes for high performance supercapacitors. Energy Environ Sci. 2017; 10: 1505-1516.

[341]

Wang Y, Lin X, Liu T, et al. Wood-derived hierarchically porous electrodes for high-performance all-solid-state supercapacitors. Adv Funct Mater. 2018; 28: 1806207.

[342]

Lei Z, Liu L, Zhao H, et al. Nanoelectrode design from microminiaturized honeycomb monolith with ultrathin and stiff nanoscaffold for high-energy micro-supercapacitors. Nat Commun. 2020; 11: 299.

[343]

Moon IK, Ki B, Oh J. Three-dimensional porous stretchable supercapacitor with wavy structured PEDOT:PSS/graphene electrode. Chem Eng J. 2020; 392: 123794.

[344]

Wang Y, Li X, Hou Y, et al. Stretchable and compressible conductive foam based on Cu nanowire/MWCNT/ethylene-vinyl acetate composites for high-mass-loading supercapacitor electrode. Chem Eng J. 2021; 417: 129176.

[345]

Chang P, Mei H, Tan Y, et al. A 3D-printed stretchable structural supercapacitor with active stretchability/flexibility and remarkable volumetric capacitance. J Mater Chem A. 2020; 8: 13646-13658.

[346]

Li X, Li H, Fan X, et al. 3D-printed stretchable micro-supercapacitor with remarkable areal performance. Adv Energy Mater. 2020; 10: 1903794.

[347]

Yan Z, Chen H, Li M, et al. Observing and understanding the corrosion of silver nanowire electrode by precursor reagents and MAPbI₃ film in different environmental conditions. Adv Mater Interfaces. 2021; 8: 2001669.

[348]

Wu W. Stretchable electronics: functional materials, fabrication strategies and applications. Sci Technol Adv Mater. 2019; 20: 187-224.

[349]

Jin L, Yang S. Engineering kirigami frameworks toward real-world applications. Adv Mater. 2023:2308560.

[350]

Bagchi B, Datta P, Fernandez CS, et al. A stretchable, self-healing an. semi-transparent nanogenerator for energy harvesting and sensing. Nano Energy. 2023; 107: 108127.

[351]

Mogli G, Reina M, Chiappone A, et al. Self-powered integrated tactile sensing system based on ultrastretchable, self-healing an. 3D printable ionic conductive hydrogel. Adv Funct Mater. 2023; 34(7): 2307133.