Abstract <p>Integrated wearable thermal management technologies have greatly enhanced human adaptability to complex environments. However, conventional thermal management strategies, which lack environmental risk perception and stable human–machine interaction, are increasingly inadequate for ensuring personal health. Here, we introduce a hierarchical modular design strategy to develop a wearable intelligent thermal management film with robust electromagnetic interference (EMI) shielding capabilities. A sensitive biomimetic serpentine dual-mode temperature–humidity sensing module is coupled with a low-power electro-/photothermal conversion module to enable intelligent thermal regulation. The resulting thermal management system offers stable and sensitive front-end temperature–humidity monitoring, alongside low-power electrothermal (51.79&#xa0;°C at 1.5&#xa0;V) and photothermal (56.38&#xa0;°C at 45.51&#xa0;mW&#xa0;cm<sup>−2</sup>) temperature regulation capabilities. Additionally, the system exhibits outstanding EMI shielding performance, with an EMI SE/t value of 1600&#xa0;dB mm<sup>–1</sup> at a thickness of just 35&#xa0;μm, ensuring stable signal transmission. The hierarchical modular design enables functional allocation with higher, thereby optimizing material performance while enhancing the decoupling and synergistic effects between different functionalities. These findings provide a scalable and practical pathway for the multifunctional integration and performance optimization of next-generation flexible wearable electronic composites.<MediaObject ID="MO1"> <ImageObject Color="Color" FileRef="MediaObjects/40820_2026_2140_Figa_HTML.png" Format="PNG" Height="484" Rendition="HTML" Resolution="300" Type="LinedrawHalftone" Width="968" /> </MediaObject></p>

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Hierarchical Modular Architecture Enabling Intelligent Dynamic Thermal Management and Superior Electromagnetic Interference Shielding

  • Qi-Fan Xuan,
  • Pei-Yan Zhao,
  • Hualong Peng,
  • Shan Zhang,
  • Bo Cai,
  • Fang-Yu Niu,
  • Martin C. Koo,
  • Xiao-Bo Sun,
  • Xiangyu Jiang,
  • Guang-Sheng Wang

摘要

Abstract

Integrated wearable thermal management technologies have greatly enhanced human adaptability to complex environments. However, conventional thermal management strategies, which lack environmental risk perception and stable human–machine interaction, are increasingly inadequate for ensuring personal health. Here, we introduce a hierarchical modular design strategy to develop a wearable intelligent thermal management film with robust electromagnetic interference (EMI) shielding capabilities. A sensitive biomimetic serpentine dual-mode temperature–humidity sensing module is coupled with a low-power electro-/photothermal conversion module to enable intelligent thermal regulation. The resulting thermal management system offers stable and sensitive front-end temperature–humidity monitoring, alongside low-power electrothermal (51.79 °C at 1.5 V) and photothermal (56.38 °C at 45.51 mW cm−2) temperature regulation capabilities. Additionally, the system exhibits outstanding EMI shielding performance, with an EMI SE/t value of 1600 dB mm–1 at a thickness of just 35 μm, ensuring stable signal transmission. The hierarchical modular design enables functional allocation with higher, thereby optimizing material performance while enhancing the decoupling and synergistic effects between different functionalities. These findings provide a scalable and practical pathway for the multifunctional integration and performance optimization of next-generation flexible wearable electronic composites.