Stretchable Thermoplastic Polyurethane/Boron Nitride Nanosheet Fabrics with Highly Anisotropic Thermal Conductivity for Multi-scenario Passive Radiative Cooling

Jingwen Dong , Kang Lin , Weijun Zhao , Fengmei Su , Bing Zhou , Yuezhan Feng , Xianhu Liu , Chuntai Liu

Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (3) : 841 -852.

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Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (3) : 841 -852. DOI: 10.1007/s42765-025-00526-9
Research Article

Stretchable Thermoplastic Polyurethane/Boron Nitride Nanosheet Fabrics with Highly Anisotropic Thermal Conductivity for Multi-scenario Passive Radiative Cooling

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Abstract

Passive radiative cooling fabrics with high solar reflectance and mid-IR emissivity hold great promise for personal cooling applications. Nevertheless, most current passive radiative cooling fabrics overlook their inherent thermal conductivity, resulting in ineffective heat transfer from human skin to the environment. Herein, by constructing highly anisotropic thermal conductive thermoplastic polyurethane/boron nitride nanosheet (TPU/BNNS) fabrics via one-step electrospinning, thermal conductive cooling mechanism was introduced into passive radiative cooling fabrics. The stacked TPU/BNNS nanofibers with aligned BNNS along the fiber direction and the porous fiber network with high contact thermal resistance resulted in high thermal conductivity along the in-plane direction but low thermal conductivity along the out-of-plane direction. This high anisotropy enables rapid heat transfer along the in-plane direction to dissipate heat while blocking external heat penetration along the out-of-plane direction, thus achieving an effective conductive cooling effect. Moreover, the incorporation of BNNS increased the scattering sites for solar radiation, further improving the fabric’s solar reflectivity to 95%. Combined with the high emissivity (92.9%) provided by the intrinsic groups of TPU and BNNS, the fabric demonstrates excellent radiative cooling ability. Therefore, under the dual action of passive radiative cooling and conductive cooling, the TPU/BNNS fabric achieved a sub-environmental cooling of 12.4 °C and a personal cooling of 10.7 °C. Along with excellent breathability, stretchability, and waterproof properties, the TPU/BNNS fabric exhibits outstanding potential for outdoor personal thermal management applications.

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Keywords

Stretchable fabric / Boron nitride nanosheets / Anisotropic thermal conductivity / Passive radiative cooling / Engineering / Materials Engineering / Interdisciplinary Engineering

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Jingwen Dong, Kang Lin, Weijun Zhao, Fengmei Su, Bing Zhou, Yuezhan Feng, Xianhu Liu, Chuntai Liu. Stretchable Thermoplastic Polyurethane/Boron Nitride Nanosheet Fabrics with Highly Anisotropic Thermal Conductivity for Multi-scenario Passive Radiative Cooling. Advanced Fiber Materials, 2025, 7(3): 841-852 DOI:10.1007/s42765-025-00526-9

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References

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

LiuXH, ZhangWR, ZhangX, ZhouZG, WangCF, PanYM, HuB, LiuCT, PanCF, ShenCY. Transparent ultrahigh-molecular-weight polyethylene/MXene films with efficient UV-absorption for thermal management. Nat Commun, 2024, 15: 3076
[2]

FarooqAS, ZhangP. Fundamentals, materials and strategies for personal thermal management by next-generation textiles. Compos Part A Appl Sci Manuf, 2021, 142: 106249
[3]

ChuS, MajumdarA. Opportunities and challenges for a sustainable energy future. Nature, 2012, 488: 294
[4]

MaZ, ZhaoD, SheC, YangY, YangR. Personal thermal management techniques for thermal comfort and building energy saving. Mater Today Phys, 2021, 20: 100465
[5]

PengYC, CuiY. Advanced Textiles for Personal Thermal Management and Energy. Joule, 2020, 4: 724
[6]

LiuXJ, ZhuWK, DengPF, LiT. Redesigning natural materials for energy, water, environment, and devices. ACS Nano, 2023, 17: 18657
[7]

WuB, QiQJ, LiuL, LiuYJ, WangJ. Wearable aerogels for personal thermal management and smart devices. ACS Nano, 2024, 18: 9798
[8]

XueSD, HuangGH, ChenQ, WangXG, FanJT, ShouDH. Personal thermal management by radiative cooling and heating. Nano-Micro Lett, 2024, 16: 153
[9]

HuR, LiuYD, ShinSM, HuangSY, RenXC, ShuWC, ChengJJ, TaoGM, XuWL, ChenRK, LuoXB. Emerging materials and strategies for personal thermal management. Adv Energy Mater, 2020, 10: 1903921
[10]

YuH, ZhangSL, LianYL, LiuMX, WangMY, JiangJM, YangC, JiaSW, WuMY, LiaoYL, GouJ, JiangYD, WangJ, TaoGM. Electronic textile with passive thermal management for outdoor health monitoring. Adv Fiber Mater, 2024, 6: 1241
[11]

LeiLQ, ShiS, WangD, MengS, DaiJG, FuSH, HuJL. Recent advances in thermoregulatory clothing: materials, mechanisms, and perspectives. ACS Nano, 2023, 17: 1803
[12]

HanGJ, ChengHL, ChengYJ, ZhouB, LiuCT, FengYZ. Scalable sol–gel permeation assembly of phase change layered film toward thermal management and light-thermal driving applications. Adv Funct Mater, 2024, 31: 2401295
[13]

ZhaoWJ, DongJW, LiZY, ZhouB, LiuCT, FengYZ. Centrifugal inertia-induced directional alignment of AgNW network for preparing transparent electromagnetic interference shielding films with Joule heating ability. Adv Sci, 2024, 11: 2406758
[14]

HeL, ChenMJ, ZengFR, WangT, WeiL, FangDX, GuoSQ, DengC, ZhaoHB, WangYZ. Multiple free-radical-trapping and hydrogen-bonding-enhanced polyurethane foams with long-lasting flame retardancy, aging resistance, and toughness. Mater Horiz, 2024, 11: 4462
[15]

HsuPC, SongAY, CatryssePB, LiuC, PengY, XieJ, FanSH, CuiY. Radiative human body cooling by nanoporous polyethylene textile. Science, 2016, 353: 1019
[16]

DongJW, FengYZ, LinK, ZhouB, SuFM, LiuCT. A stretchable electromagnetic interference shielding fabric with dual-mode passive personal thermal management. Adv Funct Mater, 2024, 34: 2310774
[17]

ZhaoXZ, LiJC, DongKC, WuJQ. Switchable and tunable radiative cooling: mechanisms, applications, and perspectives. ACS Nano, 2024, 18: 18118
[18]

WuRH, SuiCX, ChenTH, ZhouZR, LiQZ, YanGB, HanY, LiangJW, HungPJ, LuoE, TalapinDV, HsuPC. Spectrally engineered textile for radiative cooling against urban heat islands. Science, 2024, 384: 1203
[19]

ZengS, PianS, SuM, WangZ, WuM, LiuX, ChenM, XiangY, WuJ, ZhangM, CenQ, TangY, ZhouX, HuangZ, WangR, AlitenaiT, 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
[20]

MaJW, ZengFR, LinXC, WangYQ, MaYH, JiaXX, ZhangJC, LiuBW, WangYZ, ZhaoHB. A photoluminescent hydrogen-bonded biomass aerogel for sustainable radiative cooling. Science, 2024, 385: 68
[21]

HeJJ, ZhangQY, WuYP, JuYS, WangY, TangSC. Scalable nanofibrous silk fibroin textile with excellent Mie scattering and high sweat evaporation ability for highly efficient passive personal thermal management. Chem Eng J, 2023, 466: 143127
[22]

WangYJ, WangTC, LiangJ, WuJW, YangMP, PanYM, HouC, LiuCT, ShenCY, TaoGM, LiuXH. Controllable-morphology polymer blend photonic metafoam for radiative cooling. Mater Horiz, 2023, 10: 5060
[23]

LiuXH, ZhangMT, HouYZ, PanYM, LiuCT, ShenCY. Hierarchically superhydrophobic stereo-complex poly(lactic acid) aerogel for daytime radiative cooling. Adv Funct Mater, 2022, 32: 2207414
[24]

YuJ, ChengHL, WangY, HeCE, ZhouB, LiuCT, FengYZ. Multiple shearing-induced high alignment in polyethylene/graphene films for enhancing thermal conductivity and solar-thermal conversion performance. Chem Eng J, 2024, 480: 148062
[25]

GaoJ, ZhouB, LiuCQ, HeCE, FengYZ, LiuCT. Carbonization welding graphene architecture for thermally conductive phase change composites with solar/electric-to-heat conversion ability. Chem Eng J, 2023, 475: 146087
[26]

LinYB, ZhongB, ChenJ, ZhangBY, YuYL. Reinforcement of microwave absorption and thermal conductivity of polydimethylsiloxane achieved by metal–organic framework-derived carbon nanotube/boron nitride flake heterogeneous structure. Carbon, 2024, 227: 119242
[27]

FengYZ, SongJZ, HanGJ, ZhouB, LiuCT, ShenCY. Transparent and stretchable electromagnetic interference shielding film with fence-like aligned silver nanowire conductive network. Small Methods, 2023, 7: 2201490
[28]

YiSQ, SunH, JinYF, ZouKK, LiJ, JiaLC, YanDX, LiZM. CNT-assisted design of stable liquid metal droplets for flexible multifunctional composites. Compos Part B Eng, 2022, 239: 109961
[29]

YaoB, XuXW, LiH, HanZB, HaoJY, YangG, XieZX, ChenYT, LiuWS, WangQ, WangH. Soft liquid-metal/elastomer foam with compression-adjustable thermal conductivity and electromagnetic interference shielding. Chem Eng J, 2021, 410: 128288
[30]

SongJN, ShenQC, ShaoHJ, DengX. Anti-environmental aging passive daytime radiative cooling. Adv Sci, 2023, 11: 2305664
[31]

DongJW, LuoSL, NingSP, YangG, PanD, JiYX, FengYZ, SuFM, LiuCT. MXene-coated wrinkled fabrics for stretchable and multifunctional electromagnetic interference shielding and electro/photo-thermal conversion applications. ACS Appl Mater Interfaces, 2021, 13: 60478
[32]

WuJW, ZhangMN, SuMY, ZhangYQ, LiangJ, ZengSN, ChenBS, CuiL, HouC, TaoGM. Robust and flexible multimaterial aerogel fabric toward outdoor passive heating. Adv Fiber Mater, 2022, 4: 1545
[33]

LiangJ, WuJ, GuoJ, LiH, ZhouX, LiangS, QiuCW, TaoG. Radiative cooling for passive thermal management towards sustainable carbon neutrality. Natl Sci Rev, 2023, 10: nwac208
[34]

FengMX, FengSJ, LiuCH, HeX, HeM, BuXH, ZhangZW, ZhouYM. Integrated passive cooling fabrics with bioinspired perspiration-wicking for outdoor personal thermal management. Compos Part B Eng, 2023, 264: 110875
[35]

LeiLQ, MengS, SiYF, ShiS, WuHB, YangJQ, HuJL. Wettability gradient-induced diode: MXene-engineered membrane for passive-evaporative cooling. Nano-Micro Lett, 2024, 16: 159
[36]

ShanXM, LiuL, WuYS, YuanDS, WangJ, ZhangCJ, WangJ. Aerogel-functionalized thermoplastic polyurethane as waterproof, breathable freestanding films and coatings for passive daytime radiative cooling. Adv Sci, 2022, 9: 2201190
[37]

XiongLH, WeiY, ChenCL, ChenX, FuQ, DengH. Thin lamellar films with enhanced mechanical properties for durable radiative cooling. Nat Commun, 2023, 14: 6129
[38]

GuB, XuQH, WangHK, PanHD, ZhaoDL. A hierarchically nanofibrous self-cleaning textile for efficient personal thermal management in severe hot and cold environments. ACS Nano, 2023, 17: 18308
[39]

FanCH, ZhangYX, LongZW, MensahA, WangQQ, LvPF, WeiQF. Dynamically tunable subambient daytime radiative cooling metafabric with Janus wettability. Adv Funct Mater, 2023, 33: 2300794
[40]

MiaoDY, WangXF, YuJY, DingB. A biomimetic transpiration textile for highly efficient personal drying and cooling. Adv Funct Mater, 2021, 31: 2008705
[41]

YanQW, DaiW, GaoJY, TanX, LvL, YingJF, LuXX, LuJB, YaoYG, WeiQP, SunR, YuJH, JiangN, ChenD, WongC-P, XiangR, MaruyamaS, LinC-T. Ultrahigh-aspect-ratio boron nitride nanosheets leading to superhigh in-plane thermal conductivity of foldable heat spreader. ACS Nano, 2021, 15: 6489
[42]

ChenY, LiuYJ, LiuXY, LiPL, LiZ, JiangPK, HuangXY. On-demand preparation of boron nitride nanosheets for functional nanocomposites. Small Methods, 2024, 8: 2301386
[43]

LiPL, WangA, FanJJ, KangQ, JiangPK, BaoH, HuangXY. Thermo-optically designed scalable photonic films with high thermal conductivity for subambient and above-ambient radiative cooling. Adv Funct Mater, 2021, 32: 2109542
[44]

ZhuangYF, ZhengK, CaoXY, FanQR, YeG, LuJX, ZhangJN, MaYM. Flexible graphene nanocomposites with simultaneous highly anisotropic thermal and electrical conductivities prepared by engineered graphene with flat morphology. ACS Nano, 2020, 14: 11733
[45]

ZhangGR, XueS, ChenF, FuQ. An efficient thermal interface material with anisotropy orientation and high through-plane thermal conductivity. Compos Sci Technol, 2023, 231: 109784
[46]

YangG, ZhangXD, ShangY, XuPH, PanD, SuFM, JiYX, FengYZ, LiuYZ, LiuCT. Highly thermally conductive polyvinyl alcohol/boron nitride nanocomposites with interconnection oriented boron nitride nanoplatelets. Compos Sci Technol, 2021, 201: 108521
[47]

JiaYY, YueXY, WangYL, YanC, ZhengGQ, DaiK, LiuCT, ShenCY. Multifunctional stretchable strain sensor based on polydopamine/reduced graphene oxide/electrospun thermoplastic polyurethane fibrous mats for human motion detection and environment monitoring. Compos Part B Eng, 2020, 183: 107696
[48]

WangZH, LiuBW, ZengFR, LinXC, ZhangJY, WangXL, WangYZ, ZhaoHB. Fully recyclable multifunctional adhesive with high durability, transparency, flame retardancy, and harsh-environment resistance. Sci Adv, 2022, 8: eadd8527
[49]

GuoHL, ZhouJ, LiQQ, LiYM, ZongW, ZhuJX, XuJS, ZhangC, LiuTX. Emerging dual-channel transition-metal-oxide quasiaerogels by self-embedded templating. Adv Funct Mater, 2020, 30: 2000024
[50]

LiZC, ZhangSL, YangZT, LiangZ, ZhouN, TaoGM, HouC. Cooling textiles provide a new solution to urban heat islands. Adv Fiber Mater, 2024.

[51]

TanMY, ChenDM, ChengY, SunHQ, ChenGQ, DongS, ZhaoGD, SunBQ, WuSQ, ZhangWZ, HanJC, HanWB, ZhangXH. Anisotropically oriented carbon films with dual-function of efficient heat dissipation and excellent electromagnetic interference shielding performances. Adv Funct Mater, 2022, 32: 2202057
[52]

HanGJ, ZhangD, KongCM, ZhouB, ShiYQ, FengYZ, LiuCT, WangDY. Flexible, thermostable and flame-resistant epoxy-based thermally conductive layered films with aligned ionic liquid-wrapped boron nitride nanosheets via cyclic layer-by-layer blade-casting. Chem Eng J, 2022, 437: 135482
[53]

XueTT, ZhuCY, YuDY, ZhangX, LaiFL, ZhangLS, ZhangC, FanW, LiuTX. Fast and scalable production of crosslinked polyimide aerogel fibers for ultrathin thermoregulating clothes. Nat Commun, 2023, 14: 8378
[54]

SongJ, ZhangW, SunZ, PanM, TianF, LiX, YeM, DengX. Durable radiative cooling against environmental aging. Nat Commun, 2022, 13: 4805
[55]

WangY, ZhangX, LiuS, LiuY, ZhouQ, ZhuT, MiaoYE, WillenbacherN, ZhangC, LiuT. Thermal-rectified gradient porous polymeric film for solar-thermal regulatory cooling. Adv Mater, 2024, 36: 2400102
[56]

LiN, WeiLM, YouMZ, ChenMT, LiHJ, LiuHJ, FangZ, BaoHF. Hierarchically structural TiO2-PVDF fiber film with particle-enhanced spectral performance for radiative sky cooling. Sol Energy, 2023, 259: 41
[57]

WangT, WuY, ShiL, HuXH, ChenM, WuLM. A structural polymer for highly efficient all-day passive radiative cooling. Nat Commun, 2021, 12: 365
[58]

GaoTT, YangZ, ChenCJ, LiYJ, FuK, DaiJQ, HitzEM, XieH, LiuBY, SongJW, BaoY, BingHL. Three-dimensional printed thermal regulation textiles. ACS Nano, 2017, 11: 11513

Funding

National Natural Science Foundation of China(52273085)

RIGHTS & PERMISSIONS

Donghua University, Shanghai, China

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