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Abstract
Hydrogel-based sensors are recognized as key players in revolutionizing robotic applications, healthcare monitoring, and the development of artificial skins. However, the primary challenge hindering the commercial adoption of hydrogel-based sensors is their lack of high stability, which arises from the high water content within the hydrogel structure, leading to freezing at subzero temperatures and drying issues if the protective layer is compromised. These factors result in a significant decline in the benefits offered by aqueous gel electrolytes, particularly in terms of mechanical properties and conductivity, which are crucial for flexible wearable electronics. Previous reports have highlighted several disadvantages associated with using cryoprotectant co-solvents and lower mechanical properties for ion-doped anti-freezing hydrogel sensors. In this study, the design and optimization of a photocrosslinkable ionic hydrogel utilizing silk methacrylate as a novel natural crosslinker are presented. This innovative hydrogel demonstrates significantly enhanced mechanical properties, including stretchability (>1825%), tensile strength (2.49 MPa), toughness (9.85 MJ m–3), and resilience (4% hysteresis), compared to its non-ion-doped counterpart. Additionally, this hydrogel exhibits exceptional nonfreezing behavior down to −85°C, anti-drying properties with functional stability up to 2.5 years, and a signal drift of only 5.35% over 2450 cycles, whereas the control variant, resembling commonly reported hydrogels, exhibits a signal drift of 149.8%. The successful application of the developed hydrogel in advanced robotics, combined with the pioneering demonstration of combinatorial commanding using a single sensor, could potentially revolutionize sensor design, elevating it to the next level and benefiting various fields.
Keywords
antidrying
/
antifreezing
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flexible electronics
/
hydrogels
/
robotics
/
silk fibroin
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Masoud Hasany, Mohammad Kohestanian, Azar Najafi Tireh Shabankareh, Parinaz Nezhad-Mokhtari, Mehdi Mehrali.
Ultra-stretchable, super-tough, and highly stable ion-doped hydrogel for advanced robotic applications and human motion sensing.
InfoMat, 2025, 7(5): e12655 DOI:10.1002/inf2.12655
| [1] |
Luo Y, Abidian MR, Ahn J-H, et al. Technology roadmap for flexible sensors. ACS Nano. 2023; 17(6): 5211-5295.
|
| [2] |
Yuan Y-M, Liu B, Adibeig MR, et al. Microstructured polyelectrolyte elastomer-based ionotronic sensors with high sensitivities and excellent stability for artificial skins. Adv Mater. 2024; 36(11): e2310429.
|
| [3] |
Araromi OA, Graule MA, Dorsey KL, et al. Ultra-sensitive and resilient compliant strain gauges for soft machines. Nature. 2020; 587(7833): 219-224.
|
| [4] |
Liu R, Liu Y, Fu S, et al. Humidity adaptive antifreeze hydrogel sensor for intelligent control and human-computer interaction. Small. 2024; 20(24): e2308092.
|
| [5] |
Qu Y-X, Xia Q-Q, Li L-T, et al. Rational design of oil-resistant and electrically conductive fluorosilicone rubber foam nanocomposites for sensitive detectability in complex solvent environments. ACS Nano. 2024; 18(33): 22021-22033.
|
| [6] |
Lee JH, Kim SH, Heo JS, et al. Heterogeneous structure omnidirectional strain sensor arrays with cognitively learned neural networks. Adv Mater. 2023; 35(13): e2208184.
|
| [7] |
Zhao Y, Yang N, Chu X, et al. Wide-humidity range applicable, anti-freezing, and healable zwitterionic hydrogels for ion-leakage-free iontronic sensors. Adv Mater. 2023; 35(22): e2211617.
|
| [8] |
Long Y, Jiang B, Huang T, et al. Super-stretchable, anti-freezing, anti-drying organogel ionic conductor for multi-mode flexible electronics. Adv Funct Mater. 2023; 33(41): 2304625.
|
| [9] |
Wang H, Riaz MS, Ali T, Gu J, Zhong Y, Hu Y. Organo-hydrogel electrolytes with versatile environmental adaptation for advanced flexible aqueous energy storage devices. Small Science. 2023; 3(5): 2200104.
|
| [10] |
Ahn H, Kim D, Lee M, Nam KW. Challenges and possibilities for aqueous battery systems. Commun Mater. 2023; 4(1): 37.
|
| [11] |
Liang Y, Yao Y. Designing modern aqueous batteries. Nat Rev Mater. 2023; 8(2): 109-122.
|
| [12] |
Morelle XP, Illeperuma WR, Tian K, Bai R, Suo Z, Vlassak JJ. Highly stretchable and tough hydrogels below water freezing temperature. Adv Mater. 2018; 30(35): e1801541.
|
| [13] |
Gao W, Lei Z, Zhang C, Liu X, Chen Y. Stretchable and freeze-tolerant organohydrogel thermocells with enhanced thermoelectric performance continually working at subzero temperatures. Adv Funct Mater. 2021; 31(43): 2104071.
|
| [14] |
Song Y, Niu L, Ma P, Li X, Feng J, Liu Z. Rapid preparation of antifreezing conductive hydrogels for flexible strain sensors and supercapacitors. ACS Appl Mater Interfaces. 2023; 15(7): 10006-10017.
|
| [15] |
Jian Y, Handschuh-Wang S, Zhang J, Lu W, Zhou X, Chen T. Biomimetic anti-freezing polymeric hydrogels: keeping soft-wet materials active in cold environments. Mater Horiz. 2021; 8(2): 351-369.
|
| [16] |
Zhang Y, Wang Y, Guan Y, Zhang Y. Peptide-enhanced tough, resilient and adhesive eutectogels for highly reliable strain/pressure sensing under extreme conditions. Nat Commun. 2022; 13(1): 6671.
|
| [17] |
Chao Y, Li Y, Wang H, et al. Facile and fast preparation of stretchable, self-adhesive, moisturizing, antifreezing and conductive tough hydrogel for wearable strain sensors. J Mater Chem C. 2024; 12(12): 4406-4416.
|
| [18] |
Kadumudi FB, Hasany M, Pierchala MK, et al. The manufacture of unbreakable bionics via multifunctional and self-healing silk-graphene hydrogels. Adv Mater. 2021; 33(35): e2100047.
|
| [19] |
Karolina Pierchala M, Kadumudi FB, Mehrali M, et al. Soft electronic materials with combinatorial properties generated via mussel-inspired chemistry and halloysite nanotube reinforcement. ACS Nano. 2021; 15(6): 9531-9549.
|
| [20] |
He Z, Yuan W. Adhesive, stretchable, and transparent organohydrogels for antifreezing, antidrying, and sensitive ionic skins. ACS Appl Mater Interfaces. 2021; 13(1): 1474-1485.
|
| [21] |
Wu Z, Yang X, Wu J. Conductive hydrogel- and organohydrogel-based stretchable sensors. ACS Appl Mater Interfaces. 2021; 13(2): 2128-2144.
|
| [22] |
Yu X, Zhang H, Wang Y, et al. Highly stretchable, ultra-soft, and fast self-healable conductive hydrogels based on polyaniline nanoparticles for sensitive flexible sensors. Adv Funct Materi. 2022; 32(33): 2204366.
|
| [23] |
Gao H, Zhao Z, Cai Y, et al. Adaptive and freeze-tolerant heteronetwork organohydrogels with enhanced mechanical stability over a wide temperature range. Nat Commun. 2017; 8(1): 15911.
|
| [24] |
Liu Y, Li H, Wang X, et al. Flexible supercapacitors with high capacitance retention at temperatures from −20 to 100°C based on DMSO-doped polymer hydrogel electrolytes. J Mater Chem A. 2021; 9(20): 12051-12059.
|
| [25] |
Ye Y, Zhang Y, Chen Y, Han X, Jiang F. Cellulose nanofibrils enhanced, strong, stretchable, freezing-tolerant ionic conductive organohydrogel for multi-functional sensors. Adv Funct Mater. 2020; 30(35): 2003430.
|
| [26] |
Bai C, Li X, Cui X, et al. Transparent stretchable thermogalvanic PVA/gelation hydrogel electrolyte for harnessing solar energy enabled by a binary solvent strategy. Nano Energy. 2022; 100: 107449.
|
| [27] |
Fang R, Li X, Khan SA, et al. Anhydrous thermogalvanic gel for simultaneous waste heat recovery and thermal management of electronics. ACS Appl Polym Mater. 2023; 5(7): 4628-4635.
|
| [28] |
Li N, Wang Z, Yang X, et al. Deep-learning-assisted thermogalvanic hydrogel e-skin for self-powered signature recognition and biometric authentication. Adv Funct Mater. 2024; 34(18): 2314419.
|
| [29] |
Li W, Zhang Z, Han B, Hu S, Xie Y, Yang G. Effect of water and organic solvents on the ionic dissociation of ionic liquids. J Phys Chem B. 2007; 111(23): 6452-6456.
|
| [30] |
Zhang W, Chen X, Wang Y, Wu L, Hu Y. Experimental and modeling of conductivity for electrolyte solution systems. ACS Omega. 2020; 5(35): 22465-22474.
|
| [31] |
Zhou L, Zhao B, Liang J, et al. Low hysteresis, water retention, anti-freeze multifunctional hydrogel strain sensor for human-machine interfacing and real-time sign language translation. Mater Horiz. 2024; 11(16): 3856-3866.
|
| [32] |
Hou LX, Ju H, Hao XP, et al. Intrinsic anti-freezing and unique phosphorescence of glassy hydrogels with ultrahigh stiffness and toughness at low temperatures. Adv Mater. 2023; 35(21): e2300244.
|
| [33] |
Liu X, Ji X, Zhu R, Gu J, Liang J. A microphase-separated design toward an all-round ionic hydrogel with discriminable and anti-disturbance multisensory functions. Adv Mater. 2024; 36(15): e2309508.
|
| [34] |
Zhao B, Chen Q, Da G, Yao J, Shao Z, Chen X. A highly stretchable and anti-freezing silk-based conductive hydrogel for application as a self-adhesive and transparent ionotronic skin. J Mater Chem C. 2021; 9(28): 8955-8965.
|
| [35] |
Wang C, Xia K, Zhang Y, Kaplan DL. Silk-based advanced materials for soft electronics. Acc Chem Res. 2019; 52(10): 2916-2927.
|
| [36] |
Kim SH, Hong H, Ajiteru O, et al. 3D bioprinted silk fibroin hydrogels for tissue engineering. Nat Protoc. 2021; 16(12): 5484-5532.
|
| [37] |
Kim SH, Yeon YK, Lee JM, et al. Precisely printable and biocompatible silk fibroin bioink for digital light processing 3D printing. Nat Commun. 2018; 9(1): 1620.
|
| [38] |
Zheng H, Lin N, He Y, Zuo B. Self-healing, self-adhesive silk fibroin conductive hydrogel as a flexible strain sensor. ACS Appl Mater Interfaces. 2021; 13(33): 40013-40031.
|
| [39] |
Zheng H, Chen M, Sun Y, Zuo B. Self-healing, wet-adhesion silk fibroin conductive hydrogel as a wearable strain sensor for underwater applications. Chem Eng J. 2022; 446: 136931.
|
| [40] |
Ling S, Qi Z, Knight DP, Shao Z, Chen X. Synchrotron FTIR microspectroscopy of single natural silk fibers. Biomacromolecules. 2011; 12(9): 3344-3349.
|
| [41] |
Wang Y, Ma R, Hu K, et al. Dramatic enhancement of graphene oxide/silk nanocomposite membranes: increasing toughness, strength, and Young's modulus via annealing of interfacial structures. ACS Appl Mater Interfaces. 2016; 8(37): 24962-24973.
|
| [42] |
Yadav R, Purwar R. Influence of metal oxide nanoparticles on morphological, structural, rheological and conductive properties of mulberry silk fibroin nanocomposite solutions. Polym Test. 2021; 93: 106916.
|
| [43] |
Wang H, Zhang Y, Shao H, Hu X. A study on the flow stability of regenerated silk fibroin aqueous solution. Int J Biol Macromol. 2005; 36(1-2): 66-70.
|
| [44] |
Nele V, Wojciechowski JP, Armstrong JPK, Stevens MM. Tailoring gelation mechanisms for advanced hydrogel applications. Adv Funct Mater. 2020; 30(42): 2002759.
|
| [45] |
Feng Y, Wang S, Li Y, et al. Entanglement in smart hydrogels: fast response time, anti-freezing and anti-drying. Adv Funct Mater. 2023; 33(21): 2211027.
|
| [46] |
Ge G, Zhang Y, Shao J, et al. Stretchable, transparent, and self-patterned hydrogel-based pressure sensor for human motions detection. Adv Funct Mater. 2018; 28(32): 1802576.
|
| [47] |
Jaafar N, Naamen S, Rhaiem HB, Amara ABH. Functionalization and structural characterization of a novel nacrite-LiCl nanohybrid material. AJAC. 2015; 6(3): 202-215.
|
| [48] |
Laksono EW, Aji D. Conductivity of cellulose acetate membranes from pandan duri leaves (Pandanus tectorius) for Li-ion battery. MATEC Web Conf. 2016; 64: 04001.
|
| [49] |
Zhang Z, Raffa P. Anti-freezing conductive zwitterionic composite hydrogels for stable multifunctional sensors. Eur Polym J. 2023; 199: 112484.
|
| [50] |
Zhou B, Li Y, Chen Y, et al. In situ synthesis of highly stretchable, freeze-tolerant silk-polyelectrolyte double-network hydrogels for multifunctional flexible sensing. Chem Eng J. 2022; 446: 137405.
|
| [51] |
Zheng Z, Xu W, Wang Y, et al. High-conductivity and long-term stability strain sensor based on silk fibroin and polyvinyl alcohol hydrogels. Mater Today Commun. 2024; 38: 108465.
|
| [52] |
Tao XY, Zhu KH, Chen HM, et al. Recyclable, anti-freezing and anti-drying silk fibroin-based hydrogels for ultrasensitive strain sensors and all-hydrogel-state super-capacitors. Mater Today Chem. 2023; 32: 101624.
|
| [53] |
Wang W, Guo P, Liu X, et al. Fully polymeric conductive hydrogels with low hysteresis and high toughness as multi-responsive and self-powered wearable sensors. Adv Funct Materials. 2024; 34(32).
|
| [54] |
Yuan S, Bai J, Li S, et al. A multifunctional and selective ionic flexible sensor with high environmental suitability for tactile perception. Adv Funct Mater. 2024; 34(6): 2309626.
|
| [55] |
Cai H, Zhang D, Zhang H, et al. Trehalose-enhanced ionic conductive hydrogels with extreme stretchability, self-adhesive and anti-freezing abilities for both flexible strain sensor and all-solid-state supercapacitor. Chem Eng J. 2023; 472: 144849.
|
| [56] |
Cao Q, Shu Z, Zhang T, Ji W, Chen J, Wei Y. Highly elastic, sensitive, stretchable, and skin-inspired conductive sodium alginate/polyacrylamide/gallium composite hydrogel with toughness as a flexible strain sensor. Biomacromolecules. 2022; 23(6): 2603-2613.
|
| [57] |
Chen Z-J, Shen T-Y, Zhang M-H, et al. Tough, anti-fatigue, self-adhesive, and anti-freezing hydrogel electrolytes for dendrite-free flexible zinc ion batteries and strain sensors. Adv Funct Mater. 2024; 34(26): 2314864.
|
| [58] |
Gao Z-Q, Liu C-H, Zhang S-L, et al. Lanternarene-based self-sorting double-network hydrogels for flexible strain sensors. Small. 2024; 20(43): e2404231.
|
| [59] |
Guan S, Xu C, Dong X, Qi M. A highly tough, fatigue-resistant, low hysteresis hybrid hydrogel with a hierarchical cross-linked structure for wearable strain sensors. J Mater Chem A. 2023; 11(28): 15404-15415.
|
| [60] |
Han X, Lu T, Wang H, Zhang Z, Lu S. Self-healing and freeze-resistant boat-fruited sterculia seed polysaccharide/silk fiber hydrogel for wearable strain sensors. ACS Sustain Chem Eng. 2023; 11(37): 13756-13764.
|
| [61] |
Liu R, Liu W, Chen J, et al. Acrylate copolymer-reinforced hydrogel electrolyte for strain sensors and flexible supercapacitors. Batteries. 2023; 9(6): 304.
|
| [62] |
Ma Y, Zhang D, Wang Z, et al. Self-adhesive, anti-freezing MXene-based hydrogel strain sensor for motion monitoring and handwriting recognition with deep learning. ACS Appl Mater Interfaces. 2023; 15(24): 29413-29424.
|
| [63] |
Su H, Guo Q, Qiao C, Ji X, Gai L, Liu L. Lignin-alkali metal ion self-catalytic system initiated rapid polymerization of hydrogel electrolyte with high strength and anti-freezing ability. Adv Funct Mater. 2024; 34(25): 2316274.
|
| [64] |
Sun Z, Dong C, Chen B, et al. Strong, tough, and anti-swelling supramolecular conductive hydrogels for amphibious motion sensors. Small. 2023; 19(44): e2303612.
|
| [65] |
Xu L, Chen Y, Yu M, et al. NIR light-induced rapid self-healing hydrogel toward multifunctional applications in sensing. Nano Energy. 2023; 107: 108119.
|
| [66] |
Eisele U. Introduction to Polymer Physics. Springer; 1990.
|
| [67] |
Wang H, Liu B, Chen D, et al. Low hysteresis zwitterionic supramolecular polymer ion-conductive elastomers with anti-freezing properties, high stretchability, and self-adhesion for flexible electronic devices. Mater Horiz. 2024; 11(11): 2628-2642.
|
| [68] |
Zhang Y, Liu H, Wang P, et al. Stretchable, transparent, self-adhesive, anti-freezing and ionic conductive nanocomposite hydrogels for flexible strain sensors. Eur Polym J. 2023; 186: 111824.
|
| [69] |
Fang L, Zhang C, Ge W, et al. Facile spinning of tough and conductive eutectogel fibers via Li+-induced dense hydrogen-bond networks. Chem Eng J. 2023; 478: 147405.
|
| [70] |
Wang Y, Wei Z, Ji T, Bai R, Zhu H. Highly ionic conductive, stretchable, and tough ionogel for flexible solid-state supercapacitor. Small. 2024; 20(20): e2307019.
|
| [71] |
Min Park S, Hyeok CU. Exceptionally flexible and stable quasi-solid-state supercapacitors via salt-in-polyampholytes electrolyte with non-freezable properties. Chem Eng J. 2024; 479: 147384.
|
| [72] |
Lu Y, Yue Y, Ding Q, et al. Environment-tolerant ionic hydrogel-elastomer hybrids with robust interfaces, high transparence, and biocompatibility for a mechanical-thermal multimode sensor. InfoMat. 2023; 5(4): e12409.
|
| [73] |
Cai C, Wen C, Zhao W, et al. Environment-resistant organohydrogel-based sensor enables highly sensitive strain, temperature, and humidity responses. ACS Appl Mater Interfaces. 2022; 14(20): 23692-23700.
|
| [74] |
Wang Y, Song L, Wang Q, et al. Multifunctional acetylated distarch phosphate based conducting hydrogel with high stretchability, ultralow hysteresis and fast response for wearable strain sensors. Carbohydr Polym. 2023; 318: 121106.
|
| [75] |
Qiao D, Tu W, Wang Z, et al. Influence of crosslinker amount on the microstructure and properties of starch-based superabsorbent polymers by one-step preparation at high starch concentration. Int J Biol Macromol. 2019; 129: 679-685.
|
| [76] |
Dušek K, Dušková-Smrčková M. Network structure formation during crosslinking of organic coating systems. Prog Polym Sci. 2000; 25(9): 1215-1260.
|
| [77] |
Zhou J, Lin S, Zeng H, et al. Dynamic intermolecular interactions through hydrogen bonding of water promote heat conduction in hydrogels. Mater Horiz. 2020; 7(11): 2936-2943.
|
| [78] |
Hu X, Vatankhah-Varnoosfaderani M, Zhou J, Li Q, Sheiko SS. Weak hydrogen bonding enables hard, Strong, tough, and elastic hydrogels. Adv Mater. 2015; 27(43): 6899-6905.
|
| [79] |
Wu K, Li J, Li Y, et al. 3D printed silk fibroin-based hydrogels with tunable adhesion and stretchability for wearable sensing. Adv Funct Mater. 2024; 34(46): 2404455.
|
| [80] |
Han S, Tan H, Wei J, et al. Surface modification of super arborized silica for flexible and wearable ultrafast-response strain sensors with low hysteresis. Adv Sci (Weinh). 2023; 10(25): e2301713.
|
| [81] |
Rahman MT, Rahman MS, Kumar H, Kim K, Kim S. Metal-organic framework reinforced highly stretchable and durable conductive hydrogel-based triboelectric nanogenerator for biomotion sensing and wearable human-machine interfaces. Adv Funct Mater. 2023; 33(48): 2303471.
|
| [82] |
Tang J, He Y, Xu D, et al. Tough, rapid self-recovery and responsive organogel-based ionotronic for intelligent continuous passive motion system. npj Flex Electron. 2023; 7(1): 28.
|
| [83] |
Wang Y, Liu H, Yu J, et al. Ionic conductive cellulose-based hydrogels with superior long-lasting moisture and antifreezing features for flexible strain sensor applications. Biomacromolecules. 2024; 25(2): 838-852.
|
| [84] |
Li S-N, Yu Z-R, Guo B-F, et al. Environmentally stable, mechanically flexible, self-adhesive, and electrically conductive Ti3C2TX MXene hydrogels for wide-temperature strain sensing. Nano Energy. 2021; 90: 106502.
|
| [85] |
Xu S, Zhou Z, Liu Z, Sharma P. Concurrent stiffening and softening in hydrogels under dehydration. Sci Adv. 2023; 9(1): eade3240.
|
| [86] |
Chen J, Wang H, Long F, Bai S, Wang Y. Dynamic supramolecular hydrogels mediated by chemical reactions. Chem Commun (Camb). 2023; 59(96): 14236-14248.
|
| [87] |
Wu S, Peng S, Yu Y, Wang C-H. Strategies for designing stretchable strain sensors and conductors. Adv Mater Technol. 2020; 5(2): 1900908.
|
| [88] |
Chen D, Bai H, Zhu H, Zhang S, Wang W, Dong W. Anti-freezing, tough, and stretchable ionic conductive hydrogel with multi-crosslinked double-network for a flexible strain sensor. Chem Eng J. 2024; 480: 148192.
|
| [89] |
Chen H-Y, Chen Z-Y, Mao M, et al. Self-adhesive polydimethylsiloxane foam materials decorated with MXene/cellulose nanofiber interconnected network for versatile functionalities. Adv Funct Mater. 2023; 33(48): 2304927.
|
| [90] |
Kohestanian M, Hasany M, Najafi Tireh Shabankareh A, Mehrali M. Fabricating of a custom 3D-printed setup for evaluating gel-based strain sensors. Alex Eng J. 2023; 76: 517-523.
|
| [91] |
Li H, Chng CB, Zheng H, et al. Self-healable and 4D printable hydrogel for stretchable electronics. Adv Sci (Weinh). 2024; 11(13): e2305702.
|
| [92] |
Dai T, Wang J, Wu H, et al. Self-adhesive, self-healing, conductive organogel strain sensors with extreme temperature tolerance. J Mater Chem C. 2022; 10(41): 15532-15540.
|
| [93] |
Han L, Song X, Chen D, Qu R, Zhao Y. Self-powered multifunctional organic hydrogel based on poly(acrylic acid-N-isopropylacrylamide) for flexible sensing devices. Langmuir. 2023; 39(17): 6151-6159.
|
| [94] |
Wu J, Xu D, Feng Z, Zhu L, Dong C, Qiu J. Stretchable and highly sensitive polyelectrolyte microgels-enhanced polyacrylamide hydrogel composite for strain sensing. Compos Commun. 2022; 35: 101332.
|
| [95] |
Xiong X, Chen Y, Wang Z, et al. Polymerizable rotaxane hydrogels for three-dimensional printing fabrication of wearable sensors. Nat Commun. 2023; 14(1): 1331.
|
| [96] |
Sun X, Qin Z, Ye L, et al. Carbon nanotubes reinforced hydrogel as flexible strain sensor with high stretchability and mechanically toughness. Chem Eng J. 2020; 382: 122832.
|
| [97] |
Ren J, Liu Y, Wang Z, et al. An anti-swellable hydrogel strain sensor for underwater motion detection. Adv Funct Mater. 2022; 32(13): 2107404.
|
| [98] |
Mogli G, Reina M, Chiappone A, et al. Self-powered integrated tactile sensing system based on ultrastretchable, self-healing and 3D printable ionic conductive hydrogel. Adv Funct Mater. 2024; 34(7): 2307133.
|
| [99] |
Seavill P. Research with robotics. Nat Synth. 2023; 2(6): 467-468.
|
| [100] |
Zhu M, Sun Z, Lee C. Soft modular glove with multimodal sensing and augmented haptic feedback enabled by materials' multifunctionalities. ACS Nano. 2022; 16(9): 14097-14110.
|
| [101] |
Liu Y, Yiu C, Song Z, et al. Electronic skin as wireless human-machine interfaces for robotic VR. Sci Adv. 2022; 8(2): eabl6700.
|
| [102] |
Yip M, Salcudean S, Goldberg K, et al. Artificial intelligence meets medical robotics. Science. 2023; 381(6654): 141-146.
|
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