TY - JOUR
T1 - Ordered Heterostructured Aerogel with Broadband Electromagnetic Wave Absorption Based on Mesoscopic Magnetic Superposition Enhancement
AU - Jiang, Haojie
AU - Cai, Lei
AU - Pan, Fei
AU - Shi, Yuyang
AU - Cheng, Jie
AU - Yang, Yang
AU - Shi, Zhong
AU - Chai, Xiaoli
AU - Wu, Hongjing
AU - Lu, Wei
N1 - Publisher Copyright:
© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.
PY - 2023/7/27
Y1 - 2023/7/27
N2 - Demand for lightweight and efficient electromagnetic wave (EW) absorbers continues to increase with technological advances in highly integrated electronics and military applications. Although MXene-based EW absorbers have been extensively developed, more efficient electromagnetic coupling and thinner thickness are still essential. Recently, ordered heterogeneous materials have emerged as a novel design concept to address the bottleneck faced by current material development. Herein, an ordered heterostructured engineering to assemble Ti3CNTx MXenes/Aramid nanofibers/FeCo@SiO2 nanobundles (FS) aerogel (AMFS-O) is proposed, where the commonly disordered magnetic composition is transformed to ordered FS arrays that provide more powerful magnetic loss capacity. Experiments and simulations reveal that the anisotropy magnetic networks enhance the response to the magnetic field vector of EW, which effectively improves the impedance matching and makes the reflection loss (RL) peaks shift to lower frequencies, leading to the thinner matching thickness. Furthermore, the temperature stability and excellent compressibility of AMFS-O expand functionalized applications. The synthesized AMFS-O achieves full-wave absorption in X and Ku-band (8.2–18.0 GHz) at 3.0 mm with a RLmin of −41 dB and a low density of 0.008 g cm−3. These results suggest that ordered heterostructured engineering is an effective strategy for designing high-performance multifunctional EW absorbers.
AB - Demand for lightweight and efficient electromagnetic wave (EW) absorbers continues to increase with technological advances in highly integrated electronics and military applications. Although MXene-based EW absorbers have been extensively developed, more efficient electromagnetic coupling and thinner thickness are still essential. Recently, ordered heterogeneous materials have emerged as a novel design concept to address the bottleneck faced by current material development. Herein, an ordered heterostructured engineering to assemble Ti3CNTx MXenes/Aramid nanofibers/FeCo@SiO2 nanobundles (FS) aerogel (AMFS-O) is proposed, where the commonly disordered magnetic composition is transformed to ordered FS arrays that provide more powerful magnetic loss capacity. Experiments and simulations reveal that the anisotropy magnetic networks enhance the response to the magnetic field vector of EW, which effectively improves the impedance matching and makes the reflection loss (RL) peaks shift to lower frequencies, leading to the thinner matching thickness. Furthermore, the temperature stability and excellent compressibility of AMFS-O expand functionalized applications. The synthesized AMFS-O achieves full-wave absorption in X and Ku-band (8.2–18.0 GHz) at 3.0 mm with a RLmin of −41 dB and a low density of 0.008 g cm−3. These results suggest that ordered heterostructured engineering is an effective strategy for designing high-performance multifunctional EW absorbers.
KW - electromagnetic coupling
KW - increased permeability
KW - low-frequency migration
KW - magnetic-ordered heterostructure
KW - N-doped MXene aerogels
UR - http://www.scopus.com/inward/record.url?scp=85158156870&partnerID=8YFLogxK
U2 - 10.1002/advs.202301599
DO - 10.1002/advs.202301599
M3 - 文章
C2 - 37150852
AN - SCOPUS:85158156870
SN - 2198-3844
VL - 10
JO - Advanced Science
JF - Advanced Science
IS - 21
M1 - 2301599
ER -