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Open Access Research Article Issue
Bionic coral reef inspired enhanced scattering of trimetallic LDH self assembled Ti₃C₂T MXene for advanced microwave absorption
Nano Research 2025, 18(11): 94907842
Published: 25 September 2025
Abstract PDF (25.3 MB) Collect
Downloads:615

Electromagnetic wave radiation disrupts electronic devices and threatens human health. Microwave absorbing materials are essential for addressing electromagnetic pollution and military stealth applications. Advancement of electronics creates demand for absorbers with thin thickness, light weight, wide bandwidth, and strong absorption. Conventional materials suffer from poor impedance matching and limited loss mechanisms in the Ku band. Heterojunction engineering offers solutions through control of band alignment and charge distribution. The built-in electric field serves as a core mechanism for enhancing dielectric loss. However, limitations exist in understanding of formation mechanisms of built-in electric fields in multi-interface systems. This study develops a ZnNiCo-LDH/MXene composite with coral-inspired architecture. Construction of high-density Mott–Schottky interfaces occurs through electrostatic assembly of polar semiconductor units and conductive matrices. Vertical growth of flower-like layered double hydroxide (LDH) on MXene extends propagation paths of electromagnetic waves. This design creates continuous networks of built-in electric fields. Enhanced charge separation and interfacial polarization result. Performance demonstrates −49.6 dB reflection loss at 1.35 mm thickness. Effective bandwidth reaches 3.4 GHz across Ku-band frequencies. Radar cross-section simulations confirm −39.57 dB·m2 signal suppression. These achievements meet requirements of advanced absorbers. The work establishes a new paradigm for manipulation of built-in electric fields through multi-interface engineering.

Open Access Research Article Issue
High toughness MXene/ANF-CZIF67/ANF “magnetic–electric” Janus film for multifunctional low reflection electromagnetic interference shielding
Nano Research 2025, 18(8): 94907621
Published: 24 July 2025
Abstract PDF (18.1 MB) Collect
Downloads:850

Currently, the development of low-reflection electromagnetic interference (EMI) shielding composite materials for mitigating secondary electromagnetic wave pollution has become a major research focus. However, achieving thinness, high toughness, low reflectivity, and multifunctionality in flexible EMI shielding films remains a challenge. To address this issue, this study introduces a “magnetic–electric” Janus structure EMI shielding composite film composed of MXene nanosheets, carbonized ZIF-67 (CZIF67) nanoparticles and aramid nanofibers (ANF), balancing thinness, high toughness, low reflectivity, and multifunctionality. As a result, the MXene/ANF-CZIF67/ANF-4 (MACA-4) sample exhibits high tensile strength (110.0 ± 7.0 MPa), large strain tolerance (21%), and superior toughness (14.9 ± 0.9 MJ·m−3), reflecting the stress dispersion effect of the three-dimensional (3D) network structure of ANF and the strengthening effect of hydrogen bonding. The sample exhibits excellent flexibility, resistance to rubbing and folding. Even with a thickness of only 80 μm, the MACA-4 film exhibits a reflection performance (SER) as low as 4.3 to 4.5 dB in the 8.2 to 9.6 GHz band and the SET in the X-band reaches 44.8 dB. In addition, the superior conductivity of the MXene/ANF layer and the localized surface plasmon resonance effect give the MACA composite films excellent electrothermal conversion capabilities. Surprisingly, the sample also exhibited excellent infrared stealth and fire alarm properties. This work offers valuable guidance on the fabrication of ultra-thin flexible EMI shielding composites and provides an important scientific basis for the design and application of efficient EMI shielding materials.

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