Integration of photo-driven rapid self-healing and environmental robustness for durable electromagnetic wave absorbing elastomers

Junxiong Xiao , Beibei Zhan , Zhiyun Tan , Junfei Ding , Yunpeng Qu , Xiu Gong , Qiong Peng , Wei Zhong , Yanli Chen , Xiaosi Qi

InfoMat ›› 2026, Vol. 8 ›› Issue (4) : e70127

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InfoMat ›› 2026, Vol. 8 ›› Issue (4) :e70127 DOI: 10.1002/inf2.70127
RESEARCH ARTICLE
Integration of photo-driven rapid self-healing and environmental robustness for durable electromagnetic wave absorbing elastomers
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Abstract

Poor environmental robustness, especially physical damage and chemical corrosion, has remained a primary challenge in practical applications of electromagnetic (EM) wave absorbing materials. The core obstacle involves coupled trade-offs: increasing EM filler loading enhances EM attenuation but restricts polymer healing kinetics needed for rapid self-healing, while also increasing the susceptibility of fillers to oxidation and corrosion. This work proposes a novel photothermally driven MXene/self-healing polyurethane (SPU) elastomer that reconciles these competing requirements. Under xenon lamp (simulated sunlight, 1000 W m−2), MXene's photothermal conversion effectively accelerates the reversible bond exchange and chain mobility in the SPU matrix, enabling recovery of both mechanical and EM wave absorbing properties within 30 min after damage (self-healing rate over 70 times faster than under dark condition). Tuning MXene surface terminations further tailors its electrical structure and dielectric response, achieving an effective absorption bandwidth of 5.40 GHz at a thickness of 1.77 mm and a radar cross-section reduction of 23.55 dB·m2. Meanwhile, strong hydrogen bonding interaction between SPU and surface termination passivates oxidative sites and forms a protective barrier, effectively suppressing the degradation of MXene and endowing the elastomer with excellent environmental robustness under seawater and harsh acidic/alkaline media. Overall, these findings offer a versatile design paradigm for flexible, durable and self-healing EM wave absorbing materials with potential applications in next-generation wearable electronics, stealth technologies, and marine protection applications.

Keywords

electromagnetic wave absorption / environmental robustness / MXene/self-healing polyurethane / photoresponse characteristic / self-healing

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Junxiong Xiao, Beibei Zhan, Zhiyun Tan, Junfei Ding, Yunpeng Qu, Xiu Gong, Qiong Peng, Wei Zhong, Yanli Chen, Xiaosi Qi. Integration of photo-driven rapid self-healing and environmental robustness for durable electromagnetic wave absorbing elastomers. InfoMat, 2026, 8 (4) : e70127 DOI:10.1002/inf2.70127

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References

[1]

Lee J, Choi J, Seo J, et al. Reinforced concrete-inspired multiscale hierarchical metamaterial composite for synergistic enhancement across thermal, electromagnetic, and mechanical domains. Adv Funct Mater. 2026; 36:e20521.

[2]

Wu ZC, Cheng HW, Jin C, et al. Dimensional design and core–shell engineering of nanomaterials for electromagnetic wave absorption. Adv Mater. 2022; 34:2107538.

[3]

Cui Z, Yang M, Han G, et al. Recent advances in carbon composite films for high-performance, multifunctional and intelligent electromagnetic interference shielding and electromagnetic wave absorption. Carbon. 2024; 230:119627.

[4]

Lee J, Lim H, Park J, et al. Data-driven design of lightweight, interface-free metamaterial composites tailored for enhanced broadband electromagnetic absorption with robust mechanical properties. Compos Part B Eng. 2025; 306:112838.

[5]

Xie X, Liu R, Chen C, et al. Phase changes and electromagnetic wave absorption performance of XZnC (X = Fe/Co/Cu) loaded on melamine sponge hollow carbon composites. Int J Miner Metall Mater. 2025; 32(3): 566-577.

[6]

Menon AV, Choudhury B, Madras G, Bose S. ‘Trigger-free’ self-healable electromagnetic shielding material assisted by co-doped graphene nanostructures. Chem Eng J. 2020; 382:122816.

[7]

Tao J, Zhou J, Yao Z, et al. Multi-field coupled motion induces electromagnetic wave absorbing property regeneration of elastomer in marine environment. Adv Funct Mater. 2024; 34:2310640.

[8]

Markvicka EJ, Bartlett MD, Huang X, Majidi C. An autonomously electrically self-healing liquid metal–elastomer composite for robust soft-matter robotics and electronics. Nat Mater. 2018; 17(7): 618.

[9]

Cooper CB, Root SE, Michalek L, et al. Autonomous alignment and healing in multilayer soft electronics using immiscible dynamic polymers. Science. 2023; 380(6648): 935.

[10]

Ma T, Zhang Y, Ruan K, et al. Advances in 3D printing for polymer composites: a review. InfoMat. 2024; 6:e12568.

[11]

Jung J, Lee S, Kim H, et al. Self-healing electronic skin with high fracture strength and toughness. Nat Commun. 2024; 15:9763.

[12]

Zhang Y, Zhang L, Tang L, Du R, Zhang BL. S-NiSe/HG nanocomposites with balanced dielectric loss encapsulated in room-temperature self-healing polyurethane for microwave absorption and corrosion protection. ACS Nano. 2024; 18(11): 8411.

[13]

Liu Y, Wei X, He X, et al. Multifunctional shape memory composites for joule heating, self-healing, and highly efficient microwave absorption. Adv Funct Mater. 2023; 33:2211352.

[14]

Kim J, Hong M, Lee D, et al. Mechanically robust phase-change multiscale-architected metastructures integrating asymmetric MXene/T-CNF aerogel for thermal energy storage and electromagnetic interference shielding. Adv Funct Mater. 2025; 36(3):e14180.

[15]

Wang J, Guo X, Lan D, et al. Multifunctional electromagnetic wave absorbing materials: research progress from component structural design to intelligent integration. Carbon. 2025; 245:120818.

[16]

Tang J, Gao Y, Li T, Qin R, Qi Q, Meng FB. Thermoresistive network in phase-transition hydrogel: achieving on/off switchable electromagnetic interference shielding. Adv Funct Mater. 2025; 35(36):2504959.

[17]

Wang W, Qin H, Li H, et al. Heterointerface engineering via controlled nitridation enables GHz-to-THz broadband electromagnetic wave absorption in Mo1.33B2Tx nanosheets. Sci China Mater. 2025; 68(10): 3757-3766.

[18]

VahidMohammadi A, Rosen J, Gogotsi Y. The world of two-dimensional carbides and nitrides (MXenes). Science. 2021; 372(6547):eabf1581.

[19]

Wu Y, Chen C, Pan F, Li X, Lu W. High-entropy TiVNbMoC3Tx MXene hybrid with balanced dielectric–magnetic loss for high-efficient electromagnetic wave absorption with environmental stability. Chem Eng J. 2024; 499:156024.

[20]

Hao B, Chai Z, Pan F, Li M, et al. Design of mesoscopic metacomposites for electromagnetic wave absorption: enhancing performance and gaining mechanistic insights. Soft Sci. 2025; 5:39.

[21]

Liu T, Zheng Q, Cao W, et al. Dielectric genes editing MXene to switch electromagnetic functions. Adv Compos Hybrid Mater. 2024; 7(3):79.

[22]

Hao B, Zhang Y, Si H, et al. Multiscale design of dielectric composites for enhanced microwave absorption performance at elevated temperatures. Adv Funct Mater. 2025; 35(23):2423897.

[23]

Kim J, Choi Y, Jang H, et al. Thermo-chemo-mechanically robust, multifunctional MXene/PVA/PAA-Hanji textile with energy harvesting, EMI shielding, flame-retardant, and joule heating capabilities. Adv Funct Mater. 2024; 36:2411248.

[24]

Fang M, Huang L, Cui Z, et al. Phase-transition microcapacitor network in organohydrogel for absorption-dominated electromagnetic interference shielding and multi-mode intelligent responsiveness. Adv Funct Mater. 2025; 35:2418870.

[25]

Zheng S, Xu W, Liu J, et al. One-hour ambient-pressure-dried, scalable, stretchable MXene/Polyurea aerogel enables synergistic defense against high-frequency mechanical shock and electromagnetic waves. Adv Funct Mater. 2024; 34:2402889.

[26]

Kim D, Ko TY, Kim H, Lee GH, Cho S, Koo CM. Nonpolar organic dispersion of 2D Ti3C2Tx MXene flakes via simultaneous interfacial chemical grafting and phase transfer method. ACS Nano. 2019; 13(12):13818.

[27]

Naguib M, Kurtoglu M, Presser V, et al. Two-dimensional nanocrystals: two-dimensional nanocrystals produced by exfoliation of Ti3AlC2. Adv Mater. 2011; 23:4248.

[28]

Zhou L, Hu P, Bai M, et al. Harnessing the electronic spin states of single atoms for precise electromagnetic modulation. Adv Mater. 2025; 37:2418321.

[29]

Liu X, Duan Y, Wu N, et al. Modulating electromagnetic genes through bi-phase high-entropy engineering toward temperature-stable ultra-broadband megahertz electromagnetic wave absorption. Nano-Micro Lett. 2025; 17(1):164.

[30]

Luo Y, Que W, Tang Y, et al. Regulating functional groups enhances the performance of flexible microporous MXene/bacterial cellulose electrodes in supercapacitors. ACS Nano. 2024; 18(18):11675.

[31]

Zhu X, Zhang W, Lu G, Zhao H, Wang L. Ultrahigh mechanical strength and robust room-temperature self-healing properties of a polyurethane–graphene oxide network resulting from multiple dynamic bonds. ACS Nano. 2022; 16(10):16724.

[32]

Sun C, Yuan B, Han Z, et al. Transformation of the strengthening and toughening modes of a poly(urethane) elastomer with hard segments of Ti3C2 MXene and its excellent triboelectric performance. J Mater Chem A. 2024; 12:22112.

[33]

Natu V, Benchakar M, Canaff C, Habrioux A, Célérier S, Barsoum MW. A critical analysis of the x-ray photoelectron spectra of Ti3C2Tz MXenes. Matter. 2021; 4(4):1224.

[34]

Sarycheva A, Gogotsi Y. Raman spectroscopy analysis of the structure and surface chemistry of Ti3C2Tx MXene. Chem Mater. 2020; 32:3480.

[35]

Lim KRG, Shekhirev M, Wyatt BC, Anasori B, Gogotsi Y, Seh ZW. Fundamentals of MXene synthesis. Nat Synth. 2022; 1(8):601.

[36]

Li D, Zheng W, Gali SM, et al. MXenes with ordered triatomic-layer borate polyanion terminations. Nat Mater. 2024; 23(8):1085.

[37]

Du YQ, Yan Z, You W, et al. Balancing MXene surface termination and interlayer spacing enables superior microwave absorption. Adv Funct Mater. 2023; 33:2301449.

[38]

Hart JL, Hantanasirisakul K, Lang AC, et al. Control of MXenes' electronic properties through termination and intercalation. Nat Commun. 2019; 10(1):522.

[39]

Liu ZY, Wu JF, Xu WZ, Tariq MR, Zhang BL. Doped porous carbon spheres with controllable vesicle structure: preparation and the effects of pore size on electromagnetic wave absorption properties. Small. 2024; 20:2402000.

[40]

Zhang K, Yan Y, Wang Z, et al. Integration of electrical properties and polarization loss modulation on atomic Fe–N-RGO for boosting electromagnetic wave absorption. Nano Micro Lett. 2024; 17(1):46.

[41]

Yan Y, Zhang K, Qin G, et al. Phase engineering on MoS2 to realize dielectric gene engineering for enhancing microwave absorbing performance. Adv Funct Mater. 2024; 34:2316338.

[42]

Zhao J, He M, Guo H, Zhang Y, Qiu H, Lai H. Multidimensional construction of 1T-MoS2@ graphene nanosheets nanocomposites for enhanced electromagnetic wave absorption. J Mater Sci Technol. 2025; 218:35.

[43]

Guo Y, Duan Y, Liu X, et al. Construction of rGO/MOF-derived CNTs aerogel with multiple losses for multi-functional efficient electromagnetic wave absorber. Carbon. 2024; 230:119591.

[44]

Yao LH, Shu JC, Zhao JG, Zong JY, Cao MS, Cao WQ. Heterodimensional structure integrating electromagnetic functions and hybrid energy storage to drive multifunctional devices. Adv Funct Mater. 2025; 35:2503307.

[45]

Fan X, Zhang X, Li L, Fan X-X, Zhang X-C, Cao M-S. Recent progress and perspective of microwave absorption materials derived from metal-organic frameworks. Soft Sci. 2024; 4(4):43.

[46]

Zhao W, Guo Z, Lan D, et al. Construction of multicomponent bimetallic MOF-derived transition metal sulfide composites for electromagnetic wave absorption. Small. 2024; 45:e09339.

[47]

Yang S, Zhao P, Lu X, et al. Synthesis and high frequency structure simulator electromagnetic simulation of hollow NC@CeO2 nanospheres for broad absorption bandwidth. Int J Miner Metall Mater. 2025; 32(3): 678-688.

[48]

Liu A, Xu X, Qiu H, et al. Bioinspired hollow heterostructure fillers for enhanced electromagnetic interference shielding in polyimide aerogels. InfoMat. 2025; 7(11):e70060.

[49]

Wan S, Chen Y, Huang C, et al. Scalable ultrastrong MXene films with superior osteogenesis. Nature. 2024; 634(8036): 1103.

[50]

Tian Y, Hou P, Zhang H, et al. Theoretical insights on potential-dependent oxidation behaviors and antioxidant strategies of Mxenes. Nat Commun. 2024; 15:10099.

[51]

Xu X, Shi S, Tang Y, et al. Growth of NiAl-layered double hydroxide on graphene toward excellent anticorrosive microwave absorption application. Adv Sci. 2021; 8(5):2002658.

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2026 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.

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