Transparent Perfect Microwave Absorber Employing Asymmetric Resonance Cavity

Abstract The demand for high‐performance absorbers in the microwave frequencies, which can reduce undesirable radiation that interferes with electronic system operation, has attracted increasing interest in recent years. However, most devices implemented so far are opaque, limiting their use in opti...

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Bibliographic Details
Main Authors: Heyan Wang, Yilei Zhang, Chengang Ji, Cheng Zhang, Dong Liu, Zhong Zhang, Zhengang Lu, Jiubin Tan, L. Jay Guo
Format: Article
Language:English
Published: Wiley 2019-10-01
Series:Advanced Science
Subjects:
Online Access:https://doi.org/10.1002/advs.201901320
Description
Summary:Abstract The demand for high‐performance absorbers in the microwave frequencies, which can reduce undesirable radiation that interferes with electronic system operation, has attracted increasing interest in recent years. However, most devices implemented so far are opaque, limiting their use in optical applications that require high visible transparency. Here, a scheme is demonstrated for microwave absorbers featuring high transparency in the visible range, near‐unity absorption (≈99.5% absorption at 13.75 GHz with 3.6 GHz effective bandwidth) in the Ku‐band, and hence excellent electromagnetic interference shielding performance (≈26 dB). The device is based on an asymmetric Fabry–Pérot cavity, which incorporates a monolayer graphene and a transparent ultrathin (8 nm) doped silver layer as absorber and reflector, and fused silica as the middle dielectric layer. Guided by derived formulism, this asymmetric cavity is demonstrated with microwaves near‐perfectly and exclusively absorbs in the ultrathin graphene film. The peak absorption frequency of the cavity can be readily tuned by simply changing the thickness of the dielectric spacer. The approach provides a viable solution for a new type of microwave absorber with high visible transmittance, paving the way towards applications in the area of optics.
ISSN:2198-3844