超材料
气凝胶
材料科学
微波食品加热
热导率
光电子学
碳纳米管
热的
电磁辐射
过热(电)
电磁场
宽带
超材料吸收剂
稳健性(进化)
内部加热
噪音(视频)
纳米管
纳米技术
电磁学
衰减
光子超材料
异质结
传热
电场
热能
领域(数学)
保温
近场和远场
作者
Yang Liu,Kokila Khanal,Weimeng Chu,Sreekanth Ginnaram,Yibao Zhao,Chunlin Jia,Udeshwari Jamwal,Jiaqi Tao,Lvtong Duan,Wentao Yan,Yong Yang
标识
DOI:10.1002/advs.202521820
摘要
In the new generation of communication technologies, intelligent transportation, and energy management and other emerging industrial areas, electromagnetic waves (EMW), acoustics, and thermodynamics coexist in coupled and superimposed forms. Future smart living scenarios require simultaneous mitigation of electromagnetic (EM) interference, noise pollution, and thermal flow impacts. Based on this, this study proposes constructing aerogel metamaterials to achieve integrated regulation of microwave, acoustic, and thermal field. At the microscopic scale, multiple heterogeneous interfaces are formed through the interaction between aramid nanofibers (ANF), carbon nanotube (CNT), and liquid metal (LM). At the macroscopic scale, multi-stage resonant structures are designed to balance multiple physical fields. The aerogel metamaterial is fabricated via Direct-Ink-Writing (DIW) and freeze-drying. Ultimately, the metamaterial achieves ultra-wideband microwave attenuation (MA) from 2.65-18 GHz and TE/TM dual-polarization robustness at oblique incidence approaching 70°; the broadband noise reduction effect in the 2800-6400 Hz; and thermal suppression where the upper surface temperature remains only one-third of the heating field at 120°C after 30 min. The thermal conductivity of the sample is as low as 0.3649 W/m · K. While the density is only 35 mg/cm3. This study reveals the multi-physics field cross-scale synergistic mechanism and provides a new pathway for the integrated multi-physics field regulation application.
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