Bio-imitative Synergistic Color-Changing and Shape-Morphing Elastic Fibers with a Liquid Metal Core

Seonwoo Mun; Sangmin Lee; Kwak Jin Bae; Yejin Bae; Hye-Min Lee; Byung-Joo Kim; Jaesang Yu; Sungjune Park

doi:10.1007/s42765-024-00399-4

Advanced Fiber Materials ›› 2024, Vol. 6 ›› Issue (3) : 900-910. DOI: 10.1007/s42765-024-00399-4

Research Article

Bio-imitative Synergistic Color-Changing and Shape-Morphing Elastic Fibers with a Liquid Metal Core

Author information +

History +

Abstract

The systematic integration of color-changing and shape-morphing abilities into entirely soft devices is a compelling strategy for creating adaptive camouflage, electronic skin, and wearable healthcare devices. In this study, we developed soft actuators capable of color change and programmable shape morphing using elastic fibers with a liquid metal core. Once the hollow elastic fiber with the thermochromic pigment was fabricated, liquid metal (gallium) was injected into the core of the fiber. Gallium has a relatively low melting point (29.8 °C); thus, fluidity and metallic conductivity are preserved while strained. The fiber can change color by Joule heating upon applying a current through the liquid metal core and can also be actuated by the Lorentz force caused by the interaction between the external magnetic field and the magnetic field generated around the liquid metal core when a current is applied. Based on this underlying principle, we demonstrated unique geometrical actuations, including flower-like blooming, winging butterflies, and the locomotion of coil-shaped fibers. The color-changing and shape-morphing elastic fiber actuators presented in this study can be utilized in artificial skin, soft robotics, and actuators.

Keywords

Electromagnetic actuator / Liquid metal / Soft electronic / Thermochromic elastic fiber / Bio-inspired actuator

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Seonwoo Mun, Sangmin Lee, Kwak Jin Bae, Yejin Bae, Hye-Min Lee, Byung-Joo Kim, Jaesang Yu, Sungjune Park. Bio-imitative Synergistic Color-Changing and Shape-Morphing Elastic Fibers with a Liquid Metal Core. Advanced Fiber Materials, 2024, 6(3): 900‒910 https://doi.org/10.1007/s42765-024-00399-4

References

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

[1]	Kim H, Lee H, Ha I, Jung J, Won P, Cho H, Yeo J, Hong S, Han S, Kwon J, Cho K-J, Ko SH. Biomimetic color changing anisotropic soft actuators with integrated metal nanowire percolation network transparent heaters for soft robotics. Adv Funct Mater, 2018, 28: 1801847, CrossRef Google scholar

[2]	Zhang P, Debije MG, de Haan LT, Schenning APHJ. Pigmented structural color actuators fueled by near-infrared light. ACS Appl Mater Interfaces, 2022, 14: 20093, CrossRef Google scholar

[3]	Sato O, Kubo S, Gu Z-Z. Structural color films with lotus effects, superhydrophilicity, and tunable stop-bands. Accounts Chem Res, 2009, 42: 1, CrossRef Google scholar

[4]	Chung K, Yu S, Heo C-J, Shim JW, Yang S-M, Han MG, Lee H-S, Jin Y, Lee SY, Park N, Shin JH. Flexible, angle-independent, structural color reflectors inspired by morpho butterfly wings. Adv Mater, 2012, 24: 2375, CrossRef Google scholar

[5]	Yao Y, Yin C, Hong S, Chen H, Shi Q, Wang J, Lu X, Zhou N. Lanthanide-ion-coordinated supramolecular hydrogel inks for 3D printed full-color luminescence and opacity-tuning soft actuators. Chem Mat, 2020, 32: 8868, CrossRef Google scholar

[6]	Miller R, Owens SJ, Rørslett B. Plants and colour: Flowers and pollination. Opt Laser Technol, 2011, 43: 282, CrossRef Google scholar

[7]	Hanlon R. Cephalopod dynamic camouflage. Curr Biol, 2007, 17: R400, CrossRef Google scholar

[8]	Shi H, Wu S, Si M, Wei S, Lin G, Liu H, Xie W, Lu W, Chen T. Cephalopod-inspired design of photomechanically modulated display systems for on-demand fluorescent patterning. Adv Mater, 2022, 34: 2107452, CrossRef Google scholar

[9]	Xu L, Wagner RJ, Liu S, He Q, Li T, Pan W, Feng Y, Feng H, Meng Q, Zou X. Locomotion of an untethered, worm-inspired soft robot driven by a shape-memory alloy skeleton. Sci Rep, 2022, 12: 12392, CrossRef Google scholar

[10]	Liu Y-Q, Chen Z-D, Han D-D, Mao J-W, Ma J-N, Zhang Y-L, Sun H-B. Bioinspired Soft Robots Based on the Moisture-Responsive Graphene Oxide. Adv Sci, 2021, 8: 2002464, CrossRef Google scholar

[11]	Lu H, Zhang M, Yang Y, Huang Q, Fukuda T, Wang Z, Shen Y. A bioinspired multilegged soft millirobot that functions in both dry and wet conditions. Nat Commun, 2018, 9: 3944, CrossRef Google scholar

[12]	Rus D, Tolley MT. Design, fabrication and control of soft robots. Nature, 2015, 521: 467, CrossRef Google scholar

[13]	Coyle S, Majidi C, LeDuc P, Hsia KJ. Bio-inspired soft robotics: Material selection, actuation, and design. Extreme Mech Lett, 2018, 22: 51, CrossRef Google scholar

[14]	Cheng NG, Gopinath A, Wang L, Iagnemma K, Hosoi AE. Thermally tunable, self-healing composites for soft robotic applications. Macromol Mater Eng, 2014, 299: 1279, CrossRef Google scholar

[15]	Tonazzini A, Mintchev S, Schubert B, Mazzolai B, Shintake J, Floreano D. Variable stiffness fiber with self-healing capability. Adv Mater, 2016, 28: 10142, CrossRef Google scholar

[16]	Babu KF, Choi WM. Thermal actuation properties of bimorph based on PVDF/rGO composites. Compos Sci Technol, 2016, 122: 82, CrossRef Google scholar

[17]	Aouraghe MA, Mengjie Z, Qiu Y, Fujun X. Low-voltage activating, fast responding electro-thermal actuator based on carbon nanotube film/PDMS composites. Adv Fiber Mater, 2021, 3: 38, CrossRef Google scholar

[18]	He J, Ren M, Dong L, Wang Y, Wei X, Cui B, Wu Y, Zhao Y, Di J, Li Q. High-temperature-tolerant artificial muscles using poly (p-phenylene benzobisoxazole) composite yarns. Adv Fiber Mater, 2022, 4: 1256, CrossRef Google scholar

[19]	Hu X, Li J, Li S, Zhang G, Wang R, Liu Z, Chen M, He W, Yu K, Zhai W. Morphology modulation of artificial muscles by thermodynamic-twist coupling. Natl Sci Rev, 2023, 10: nwac96, CrossRef Google scholar

[20]	Li S, Zhang R, Zhang G, Shuai L, Chang W, Hu X, Zou M, Zhou X, An B, Qian D. Microfluidic manipulation by spiral hollow-fibre actuators. Nat Commun, 2022, 13: 1331, CrossRef Google scholar

[21]	Pelrine R, Kornbluh R, Pei Q, Joseph J. High-speed electrically actuated elastomers with strain greater than 100%. Science, 2000, 287: 836, CrossRef Google scholar

[22]	Ji X, Liu X, Cacucciolo V, Imboden M, Civet Y, El Haitami A, Cantin S, Perriard Y, Shea H. An autonomous untethered fast soft robotic insect driven by low-voltage dielectric elastomer actuators. Sci Robot, 2019, 4: eaaz6451, CrossRef Google scholar

[23]	Wu S, Ze Q, Zhang R, Hu N, Cheng Y, Yang F, Zhao R. Symmetry-breaking actuation mechanism for soft robotics and active metamaterials. ACS Appl Mater Interfaces, 2019, 11: 41649, CrossRef Google scholar

[24]	Zhang Y, Wang Q, Yi S, Lin Z, Wang C, Chen Z, Jiang L. 4D printing of magnetoactive soft materials for on-demand magnetic actuation transformation. ACS Appl Mater Interfaces, 2021, 13: 4174, CrossRef Google scholar

[25]	Ju Y, Hu R, Xie Y, Yao J, Li X, Lv Y, Han X, Cao Q, Li L. Reconfigurable magnetic soft robots with multimodal locomotion. Nano Energy, 2021, 87, CrossRef Google scholar

[26]	Yu Y, Nakano M, Ikeda T. Directed bending of a polymer film by light. Nature, 2003, 425: 145, CrossRef Google scholar

[27]	Yu Y, Li L, Liu E, Han X, Wang J, Xie Y-X, Lu C. Light-driven core-shell fiber actuator based on carbon nanotubes/liquid crystal elastomer for artificial muscle and phototropic locomotion. Carbon, 2022, 187: 97, CrossRef Google scholar

[28]	Yue Y, Norikane Y, Azumi R, Koyama E. Light-induced mechanical response in crosslinked liquid-crystalline polymers with photoswitchable glass transition temperatures. Nat Commun, 2018, 9: 3234, CrossRef Google scholar

[29]	Yang M, Wang S-Q, Liu Z, Chen Y, Zaworotko MJ, Cheng P, Ma J-G, Zhang Z. Fabrication of moisture-responsive crystalline smart materials for water harvesting and electricity transduction. J Am Chem Soc, 2021, 143: 7732, CrossRef Google scholar

[30]	Wei J, Jia S, Guan J, Ma C, Shao Z. Robust and highly sensitive cellulose nanofiber-based humidity actuators. ACS Appl Mater Interfaces, 2021, 13: 54417, CrossRef Google scholar

[31]	Zakeri R, Zakeri R. Bio inspired general artificial muscle using hybrid of mixed electrolysis and fluids chemical reaction (HEFR). Sci Rep, 2022, 12: 3627, CrossRef Google scholar

[32]	Hines L, Petersen K, Lum GZ, Sitti M. Soft actuators for small-scale robotics. Adv Mater, 2017, 29: 1603483, CrossRef Google scholar

[33]	Yu K, Ge Q, Qi HJ. Reduced time as a unified parameter determining fixity and free recovery of shape memory polymers. Nat Commun, 2014, 5: 3066, CrossRef Google scholar

[34]	Meng Y, Jiang J, Anthamatten M. Body temperature triggered shape-memory polymers with high elastic energy storage capacity. J Polym Sci Pt B-Polym Phys, 2016, 54: 1397, CrossRef Google scholar

[35]	Mao G, Schiller D, Danninger D, Hailegnaw B, Hartmann F, Stockinger T, Drack M, Arnold N, Kaltenbrunner M. Ultrafast small-scale soft electromagnetic robots. Nat Commun, 2022, 13: 4456, CrossRef Google scholar

[36]	Ni X, Luan H, Kim J-T, Rogge SI, Bai Y, Kwak JW, Liu S, Yang DS, Li S, Li S, Li Z, Zhang Y, Wu C, Ni X, Huang Y, Wang H, Rogers JA. Soft shape-programmable surfaces by fast electromagnetic actuation of liquid metal networks. Nat Commun, 2022, 13: 5576, CrossRef Google scholar

[37]	Yunas J, Mulyanti B, Hamidah I, Mohd Said M, Pawinanto RE, Wan Ali WAF, Subandi A, Hamzah AA, Latif R, Yeop MB. Polymer-based MEMS electromagnetic actuator for biomedical application: a review. Polymers, 2020, 12: 1184, CrossRef Google scholar

[38]	Mao G, Drack M, Karami-Mosammam M, Wirthl D, Stockinger T, Schwödiauer R, Kaltenbrunner M. Soft electromagnetic actuators. Sci Adv, 2020, 6: eabc0251, CrossRef Google scholar

[39]	Morin SA, Shepherd RF, Kwok SW, Stokes AA, Nemiroski A, Whitesides GM. Camouflage and display for soft machines. Science, 2012, 337: 828, CrossRef Google scholar

[40]	Wang Y, Cui H, Zhao Q, Du X. Chameleon-inspired structural-color actuators. Matter, 2019, 1: 626, CrossRef Google scholar

[41]	Uh K, Yoon B, Lee CW, Kim J-M. An electrolyte-free conducting polymer actuator that displays electrothermal bending and flapping wing motions under a magnetic field. ACS Appl Mater Interfaces, 2016, 8: 1289, CrossRef Google scholar

[42]	Gao P, Li J, Shi Q. A hollow polyethylene fiber-based artificial muscle. Adv Fiber Mater, 2019, 1: 214, CrossRef Google scholar

[43]	Liu Y, Gao M, Mei S, Han Y, Liu J. Ultra-compliant liquid metal electrodes with in-plane self-healing capability for dielectric elastomer actuators. Appl Phys Lett, 2013, 103, CrossRef Google scholar

[44]	Wissman J, Finkenauer L, Deseri L, Majidi C. Saddle-like deformation in a dielectric elastomer actuator embedded with liquid-phase gallium-indium electrodes. J Appl Phys, 2014, 116, CrossRef Google scholar

[45]	He W, Zhang R, Cheng Y, Zhang C, Zhou X, Liu Z, Hu X, Liu Z, Sun J, Wang Y. Intrinsic elastic conductors with internal buckled electron pathway for flexible electromagnetic interference shielding and tumor ablation. Sci China Mater, 2020, 63: 1318, CrossRef Google scholar

[46]	Liu Z, Fang S, Moura F, Ding J, Jiang N, Di J, Zhang M, Lepró X, Galvao D, Haines C. Hierarchically buckled sheath-core fibers for superelastic electronics, sensors, and muscles. Science, 2015, 349: 400, CrossRef Google scholar

[47]	Park S, Baugh N, Shah HK, Parekh DP, Joshipura ID, Dickey MD. Ultrastretchable elastic shape memory fibers with electrical conductivity. Adv Sci, 2019, 6: 1901579, CrossRef Google scholar

[48]	Hong K, Choe M, Kim S, Lee H-M, Kim B-J, Park S. An Ultrastretchable electrical switch fiber with a magnetic liquid metal core for remote magnetic actuation. Polymers, 2021, 13: 2407, CrossRef Google scholar

[49]	Lee S, Bhuyan P, Bae KJ, Yu J, Jeon H, Park S. Interdigitating elastic fibers with a liquid metal core toward ultrastretchable and soft capacitive sensors: from 1D fibers to 2D electronics. ACS Appl Electron Mater, 2022, 4: 6275, CrossRef Google scholar

[50]	Dong C, Leber A, Das Gupta T, Chandran R, Volpi M, Qu Y, Nguyen-Dang T, Bartolomei N, Yan W, Sorin F. High-efficiency super-elastic liquid metal based triboelectric fibers and textiles. Nat Commun, 2020, 11: 3537, CrossRef Google scholar

[51]	Zheng L, Zhu M, Wu B, Li Z, Sun S, Wu P. Conductance-stable liquid metal sheath-core microfibers for stretchy smart fabrics and self-powered sensing. Sci Adv, 2021, 7: eabg4041, CrossRef Google scholar

[52]	Do TN, Visell Y. Stretchable, twisted conductive microtubules for wearable computing, robotics, electronics, and healthcare. Sci Rep, 2017, 7: 1753, CrossRef Google scholar

[53]	Sin D, Singh VK, Bhuyan P, Wei Y, Lee H-M, Kim B-J, Park S. Ultrastretchable thermo- and mechanochromic fiber with healable metallic conductivity. Adv Electron Mater, 2021, 7: 2100146, CrossRef Google scholar

[54]	Tachibana D, Murakami K, Kozaki T, Matsuda R, Isoda Y, Nakamura F, Isano Y, Ueno K, Fuchiwaki O, Ota H. Ultrafast and highly deformable electromagnetic hydrogel actuators assembled from liquid metal gel fiber. Adv Intell Syst, 2022, 4: 2100212, CrossRef Google scholar

[55]	Jin Y, Lin Y, Kiani A, Joshipura ID, Ge M, Dickey MD. Materials tactile logic via innervated soft thermochromic elastomers. Nat Commun, 2019, 10: 4187, CrossRef Google scholar

[56]	Ferdous W, Manalo A, AlAjarmeh OS, Zhuge Y, Mohammed AA, Bai Y, Aravinthan T, Schubel P. Bending and shear behaviour of waste rubber concrete-filled FRP tubes with external flanges. Polymers, 2021, 13: 2500, CrossRef Google scholar

[57]	Eacock A, Rowland HM, van’t Hof AE, Yung CJ, Edmonds N, Saccheri IJ. Adaptive colour change and background choice behaviour in peppered moth caterpillars is mediated by extraocular photoreception. Commun Biol, 2019, 2: 286, CrossRef Google scholar

[58]	Mutlu S, Yasa O, Erin O, Sitti M. Magnetic resonance imaging-compatible optically powered miniature wireless modular lorentz force actuators. Adv Sci, 2021, 8: 2002948, CrossRef Google scholar

[59]	Li W, Chen H, Yi Z, Fang F, Guo X, Wu Z, Gao Q, Shao L, Xu J, Meng G, Zhang W. Self-vectoring electromagnetic soft robots with high operational dimensionality. Nat Commun, 2023, 14: 182, CrossRef Google scholar

Funding

National Research Foundation of Korea(2021R1C1C1005083); National Research Foundation of Korea(RS-2023-00207836); Ministry of Trade, Industry and Energy(20013038)