Bio-inspired Tough Metafiber with Hierarchical Photonic Structures for Durable Passive Radiative Thermal Management

Xiaoyan Li , Zhiguang Guo , Yating Ji , Peibo Du , Jun Wang , Bi Xu , Fengyan Ge , Yaping Zhao , Zaisheng Cai

Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (2) : 607 -619.

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Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (2) : 607 -619. DOI: 10.1007/s42765-025-00510-3
Research Article

Bio-inspired Tough Metafiber with Hierarchical Photonic Structures for Durable Passive Radiative Thermal Management

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Abstract

Passive radiative thermal management holds substantial potential for enhancing energy efficiency and sustainability. However, few research efforts have addressed the integration of mechanical robustness and durability with the distribution and composition of photonic structures within materials. Silk fibers, known for their distinctive hierarchical morphological structure, offer a solution to these challenges by providing exceptional optical and mechanical properties. Inspired by this, we developed a silk-like tough metafiber (PMABF) that incorporated multiple scatterers through a multi-scale structural construction of nanofiber aggregates and molecular interface engineering. We show that fabrics woven with PMABF can provide high mid-infrared (MIR) emissivity (98.6%) within the atmospheric window and 86.7% reflectivity in the solar spectrum, attributed to its ellipsoidal photonic structure featuring by surface micro-/nano-particles and numerous internal voids. Through mature and scalable industrial manufacturing routes, our metafibers show excellent mechanical strength, hydrophobicity and thermal stability while maintaining effective passive radiative cooling. Practical application tests demonstrated that molecules introduced during the heterogeneous composite process significantly enhanced the metafiber’s tensile strength (125%) and compressive stress (261.5%) by forming junction welds among the nanofiber backbones to efficiently distribute the external forces. Furthermore, the superior thermal stability and flexibility of PMABF open abundant opportunities for diverse applications with demanding thermal management requirements, such as thermal protection and multi-scenario thermal camouflage.

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Keywords

Silk-like / Metafiber / Photonic structure / Molecular engineering / Radiative thermal management / Multimode thermal regulation / Engineering / Materials Engineering

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Xiaoyan Li, Zhiguang Guo, Yating Ji, Peibo Du, Jun Wang, Bi Xu, Fengyan Ge, Yaping Zhao, Zaisheng Cai. Bio-inspired Tough Metafiber with Hierarchical Photonic Structures for Durable Passive Radiative Thermal Management. Advanced Fiber Materials, 2025, 7(2): 607-619 DOI:10.1007/s42765-025-00510-3

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

WoodsJ, JamesN, KozubalE, BonnemaE, BriefK, VoellerL, RivestJ. Humidity’s impact on greenhouse gas emissions from air conditioning. Joule, 2022, 6: 726.

[2]

LiangJ, WuJ, GuoJ, LiH, ZhouX, LiangS, QiuCW, TaoG. Radiative cooling for passive thermal management towards sustainable carbon neutrality. Natl Sci Rev, 2023, 10: nwac208.

[3]

LinK, ChenS, ZengY, TszHC, ZhuY, WangX, LiuF, HuangB, ChaoY-H, WangZ, ChiTY. Hierarchically structured passive radiative cooling ceramic with high solar reflectivity. Science, 2023, 382: 691.

[4]

AgencyIEThe future of cooling: opportunities for energy-efficient air conditioning, 2018PairsInternational Energy Agency.

[5]

WangY, WangT, LiangJ, WuJ, YangM, PanY, HouC, LiuC, ShenC, TaoG, LiuX. Controllable-morphology polymer blend photonic metafoam for radiative cooling. Mater Horiz, 2023, 10: 5060.

[6]

HuangMC, YangM, GuoXJ, XueCH, WangHD, MaCQ, BaiZ, ZhouX, WangZ, LiuB-Y, WuYG, QiuCW, HouC, TaoG. Scalable multifunctional radiative cooling materials. Prog Mater Sci, 2023, 137. 101144
[7]

LiZ, ChenQ, SongY, ZhuB, ZhuJ. Fundamentals, materials, and applications for daytime radiative cooling. Adv Mater Technol, 2020, 5: 1901007.

[8]

ZhaiY, MaY, SabrinaDN, ZhaoD, LouR, TanG, YangR, YinX. Scalable-manufactured randomized glass-polymer hybrid metamaterial for daytime radiative cooling. Science, 2017, 355: 1062.

[9]

PengY, CuiY. Advanced textiles for personal thermal management and energy. Joule, 2020, 4: 724.

[10]

LinKT, HanJ, LiK, GuoC, LinH, JiaB. Radiative cooling: fundamental physics, atmospheric influences, materials and structural engineering, applications and beyond. Nano Energy, 2021, 80. 105517
[11]

YanW, DongC, XiangY, JiangS, LeberA, LokeG, XuW, HouC, ZhouS, ChenM, HuR, ShumPP, WeiL, JiaX, SorinF, TaoX, TaoG. Thermally drawn advanced functional fibers: new frontier of flexible electronics. Mater Today, 2020, 35: 168.

[12]

ChenC, FengJ, LiJ, GuoY, ShiX, PengH. Functional fiber materials to smart fiber devices. Chem Rev, 2023, 123: 613.

[13]

XiongJ, ChenJ, LeeSP. Functional fibers and fabrics for soft robotics, wearables, and human–robot interface. Adv Mater, 2021, 33: 2002640.

[14]

ChenM, LiuJ, LiP, GharaviH, HaoY, OuyangJ, HuJ, HuL, HouC, HumarI, WeiL, YangG-Z, TaoG. Fabric computing: concepts, opportunities, and challenges. The Innovavation, 2022, 3100340
[15]

MandalJ, FuY, OvervigAC, JiaM, SunK, ShiNN, ZhouH, XiaoX, YuN, YangY. Hierarchically porous polymer coatings for highly efficient passive daytime radiative cooling. Science, 2018, 362: 315.

[16]

ShiNN, TsaiC-C, CaminoF, BernardGD, YuN, WehnerR. Keeping cool: enhanced optical reflection and radiative heat dissipation in Saharan silver ants. Science, 2015, 349: 298.

[17]

ZhuB, LiW, ZhangQ, LiD, LiuX, WangY, XuN, WuZ, LiJ, LiX, CatryssePB, XuW, FanS, ZhuJ. Subambient daytime radiative cooling textile based on nanoprocessed silk. Nat Nanotechnol, 2021, 16: 1342.

[18]

LiT, ZhaiY, HeS, GanW, WeiZ, HeidarinejadM, DalgoD, MiR, ZhaoX, SongJ, DaiJ, ChenC, AiliA, VelloreA, MartiniA, YangR, SrebricJ, YinX, HuL. A radiative cooling structural material. Science, 2019, 364: 760.

[19]

YaoP, ChenZ, LiuT, LiaoX, YangZ, LiJ, JiangY, XuN, LiW, ZhuB, ZhuJ. Spider-silk-inspired nanocomposite polymers for durable daytime radiative cooling. Adv Mater, 2022, 34: 2208236.

[20]

YuX, ChanJ, ChenC. Review of radiative cooling materials: Performance evaluation and design approaches. Nano Energy, 2021, 88. 106259
[21]

ShenC, LiuX. DNA and gelatin—a cool aerogel mix. Science, 2024, 385: 30.

[22]

LiuX, ZhangM, HouY, PanY, LiuC, ShenC. Hierarchically superhydrophobic stereo-complex poly (lactic acid) aerogel for daytime radiative cooling. Adv Funct Mater, 2022, 32: 2207414.

[23]

ZengS, PianS, SuM, WangZ, WuM, LiuX, ChenM, XiangY, WuJ, ZhangM, CenQ, TangY, ZhouX, HuangZ, WangR, TunuheA, SunX, XiaZ, TianM, ChenM, MaX, YangL, ZhouJ, ZhouH, YangQ, LiX, MaY, TaoG. Hierarchical-morphology metafabric for scalable passive daytime radiative cooling. Science, 2021, 373: 692.

[24]

LiuR, WangS, ZhouZ, ZhangK, WangG, ChenC, LongY. Materials in radiative cooling technologies. Adv Mater, 2024.

[25]

XuL, SunDW, TianY, FanT, ZhuZ. Nanocomposite hydrogel for daytime passive cooling enabled by combined effects of radiative and evaporative cooling. Chem Eng J, 2023, 457. 141231
[26]

WangCH, LiuMX, JiangZY. TiO2 particle agglomeration impacts on radiative cooling films with a thickness of 50 μm. Appl Phys Lett, 2022, 121. 202204
[27]

YanZ, ZhaiH, FanD, LiQ. Biological optics, photonics and bioinspired radiative cooling. Prog Mater Sci, 2024, 144. 101291
[28]

ShiNN, TsaiC-C, CarterJM, MandalJ, OvervigAC, SfeirMY, LuM, CraigCL, BernardGD, YangY, YuN. Nanostructured fibers as a versatile photonic platform: radiative cooling and waveguiding through transverse Anderson localization. Light Sci Appl, 2018, 7: 37.

[29]

ChoiSH, KimSW, KuZ, Visbal-OnufrakMA, KimSR, ChoiKH, KoH, ChoiW, UrbasAM, GooTW, KimYL. Anderson light localization in biological nanostructures of native silk. Nat Commun, 2018, 9: 452.

[30]

LiuR, DengQ, YangZ, YangD, HanMY, LiuXY. “Nano-fishnet” structure making silk fibers tougher. Adv Funct Mater, 2016, 26: 5534.

[31]

SahooJK, HasturkO, FalcucciT, KaplanDL. Silk chemistry and biomedical material designs. Nat Rev Chem, 2023, 7: 302.

[32]

WanQ, YangM, HuJ, LeiF, ShuaiY, WangJ, HollandC, RodenburgC, YangM. Mesoscale structure development reveals when a silkworm silk is spun. Nat Commun, 2021, 12: 3711.

[33]

BüsseS, BüscherTH, KellyET, LarsH, EdgerlyJS, GorbSN. Pressure-induced silk spinning mechanism in webspinners. Soft Matter, 2019, 15: 9742.

[34]

ChenX, WangY, WangY, LiQ, LiangX, WangG, LiJ, PengR, SimaY, XuS. Ectopic expression of sericin enables efficient production of ancient silk with structural changes in silkworm. Nat Commun, 2022, 13: 6295.

[35]

LuH, JianM, GanL, ZhangY, LiS, LiangX, WangH, ZhuM, ZhangY. Highly strong and tough silk by feeding silkworms with rare earth ion-modified diets. Sci Bull, 2023, 68: 2973.

[36]

DengS, JiaS, DengX, QingY, LuoS, WuY. New insight into island-like structure driven from hydroxyl groups for high-performance superhydrophobic surfaces. Chem Eng J, 2021, 416. 129078
[37]

RollingsDAE, VeinotJGC. Polysiloxane nanofibers via surface initiated polymerization of vapor phase reagents: a mechanism of formation and variable wettability of fiber-bearing substrates. Langmuir, 2008, 24: 13653.

[38]

HeH, WeiX, YangB, LiuH, SunM, LiY, YanA, TangCY, LinY, XuL. Ultrastrong and multifunctional aerogels with hyperconnective network of composite polymeric nanofibers. Nat Commun, 2022, 13: 4242.

[39]

LiL, YangG, LyuJ, ShengZ, MaF, ZhangX. Folk arts-inspired twice-coagulated configuration-editable tough aerogels enabled by transformable gel precursors. Nat Commun, 2023, 14: 8450.

[40]

ZhangJ, ZhengJ, GaoM, XuC, ChengY, ZhuM. Nacre-mimetic nanocomposite aerogels with exceptional mechanical performance for thermal superinsulation at extreme conditions. Adv Mater, 2023, 35: 2300813.

[41]

WuM, ShaoZ, ZhaoN, ZhangR, YuanG, TianL, ZhangZ, GaoW, BaiH. Biomimetic, knittable aerogel fiber for thermal insulation textile. Science, 2023, 382: 1379.

[42]

ZimmermannJ, ReiflerFA, FortunatoG, GerhardtL-C, SeegerS. A simple, one-step approach to durable and robust superhydrophobic textiles. Adv Funct Mater, 2008, 18: 3662.

[43]

SuiC, PuJ, ChenTH, LiangJ, LaiYT, RaoY, WuR, HanY, WangK, LiX, ViswanathanV, HsuPC. Dynamic electrochromism for all-season radiative thermoregulation. Nat Sustain, 2023, 6: 428.

[44]

KuničR. Carbon footprint of thermal insulation materials in building envelopes. Energy Effic, 2017, 10: 1511.

[45]

LeiL, ShiS, WangD, MengS, DaiJG, FuS, HuJ. Recent advances in thermoregulatory clothing: materials, mechanisms, and perspectives. ACS Nano, 2023, 17: 1803.

[46]

LiuX, ZhangW, ZhangX, ZhouZ, WangC, PanY, HuB, LiuC, PanC, ShenC. Transparent ultrahigh-molecular-weight polyethylene/MXene films with efficient UV-absorption for thermal management. Nat Commun, 2024, 15: 3076.

[47]

ParkYM, HwangSH, LimH, LeeHN, KimHJ. Scalable and versatile fabrication of metallic nanofoam films with controllable nanostructure using Ar-assisted thermal evaporation. Chem Mater, 2021, 33: 205.

[48]

ZhangX, LiuX, SunB, YeH, HeC, KongL, LiG, LiuZ, LiaoG. Ultrafast, self-powered, and charge-transport-layer-free ultraviolet photodetectors based on sequentially vacuum-evaporated lead-free Cs2AgBiBr6 thin films. ACS Appl Mater Interfaces, 2021, 13: 35949.

[49]

HsuPC, LiuC, SongAY, ZhangZ, PengY, XieJ, LiuK, WuCL, CatryssePB, CaiL, ZhaiS, MajumdarA, FanS, CuiY. A dual-mode textile for human body radiative heating and cooling. Sci Adv, 2017, 3. e1700895
[50]

LiX, JiY, FanZ, DuP, XuB, CaiZ. Asymmetrical emissivity and wettability in stitching treble weave metafabric for synchronous personal thermal-moisture management. Small, 2023, 19: 2300297.

[51]

XiangB, ZhangR, ZengX, LuoY, LuoZ. An easy-to-prepare flexible dual-mode fiber membrane for daytime outdoor thermal management. Adv Fiber Mater, 2022, 4: 1058.

[52]

WangS, JiangT, MengY, YangR, TanG, LongY. Scalable thermochromic smart windows with passive radiative cooling regulation. Science, 2021, 374: 1501.

[53]

LinC, HurJ, ChaoCYH, LiuG, YaoS, LiW, HuangB. All-weather thermochromic windows for synchronous solar and thermal radiation regulation. Sci Adv, 2022, 8: eabn7359.

[54]

ErgoktasMS, BakanG, KovalskaE, FevreLWL, FieldsRP, SteinerP, YuX, SalihogluO, BalciS, Fal’koVI, NovoselovK, DryfeRAW, KocabasC. Multispectral graphene-based electro-optical surfaces with reversible tunability from visible to microwave wavelengths. Nat Photon, 2021, 15: 493.

[55]

SalihogluO, UzluHB, YakarO, AasS, BalciO, KakenovN, BalciS, OlcumS, SüzerS, KocabasC. Graphene-based adaptive thermal camouflage. Nano Lett, 2018, 18: 4541.

[56]

ChandrasekharP, ZayBJ, LawrenceD, CaldwellE, ShethR, StephanR, CornwellJ. Variable-emittance infrared electrochromic skins combining unique conducting polymers, ionic liquid electrolytes, microporous polymer membranes, and semiconductor/polymer coatings, for spacecraft thermal control. J Appl Polym Sci, 2014, 131: 40850.

[57]

GuoZ, SunC, WangJ, CaiZ, GeF. High-performance laminated fabric with enhanced photothermal conversion and joule heating effect for personal thermal management. ACS Appl Mater Interfaces, 2021, 13: 8851.

[58]

HuR, XiW, LiuY, TangK, SongJ, LuoX, WuJ, QiuCW. Thermal camouflaging metamaterials. Mater Today, 2021, 45: 120.

Funding

National Natural Science Foundation of China(NO.22176031)

Fundamental Research Funds for the Central Universities and Graduate Student Innovation Fund of Donghua University(CUSF-DH-D-2023029)

RIGHTS & PERMISSIONS

Donghua University, Shanghai, China

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