Transparent Perfect Microwave Absorber Employing Asymmetric Resonance Cavity

Wang, Heyan; Zhang, Yilei; Ji, Chengang; Zhang, Cheng; Liu, Dong; Zhang, Zhong; Lu, Zhengang; Tan, Jiubin; Guo, L. Jay

doi:10.1002/advs.201901320

Cited by 46 publications

(39 citation statements)

References 62 publications

(72 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…To observe only the signal completely reflected by the surface, a copper sheet was attached to the back of the transparent absorbing structure and was measured. Figure 7 shows the reflected power result (P re f lec = |Γ 3 | 2 × 100%) obtained from Equation (7). The measurement results confirmed a difference of up to 1.46 dB for the reflection coefficient and up to 4.68% for the X-band average reflectance.…”

Section: Measurement Of Reflection Characteristics Based On Single Near-field Antennamentioning

confidence: 73%

Design of an Optical Transparent Absorber and Defect Diagnostics Analysis Based on Near-Field Measurement

Lee

Yoon

Choi³

et al. 2021

Sensors

View full text Add to dashboard Cite

To reduce the electromagnetic wave interference caused by cavity resonance or electromagnetic wave leakage, herein, an optical transparent radar absorbing structure (RAS) was designed using transparent conductive oxides (TCOs) with a high optical transmittance and electrical conductivity, and a procedure was proposed for detecting possible defects in the fabrication and operation and for assessing the influence of the defects on the electromagnetic performance. To detect locally occurring defects in planar and three-dimensional absorbing structures, a measurement system based on an open-ended near-field antenna capable of producing small beam spots at a close distance was constructed. Moreover, the reflection characteristics of the transparent RAS were derived from a simplified multiple reflection equation, and the derived results were compared with the analysis results of an equivalent circuit model to predict the surface resistance of the TCO coating layer, based on which the presence of defects could be confirmed. By using the experimental results, the predicted surface resistance results of the coating layer and the results measured using a non-contact sheet resistance meter were compared and were found to correspond, thereby confirming the effectiveness of the proposed defect detection method.

show abstract

Section: Measurement Of Reflection Characteristics Based On Single Near-field Antennamentioning

confidence: 73%

Design of an Optical Transparent Absorber and Defect Diagnostics Analysis Based on Near-Field Measurement

Lee

Yoon

Choi³

et al. 2021

Sensors

View full text Add to dashboard Cite

show abstract

“…This is because increasing the carbonization temperature greatly increases the r of WPC, which increases the impedance mismatch between the materials and air, causing most of the incident electromagnetic waves to be reflected. In addition, during the multiple reflection and scattering process of the electromagnetic waves entering the materials, highly conductive WPC has a stronger dielectric loss mechanism, which makes them fully captured and attenuated, resulting in the excellent EMI shielding performance [39,40].…”

Section: Resultsmentioning

confidence: 99%

Ultra-light MXene aerogel/wood-derived porous carbon composites with wall-like “mortar/brick” structures for electromagnetic interference shielding

et al. 2020

View full text Add to dashboard Cite

“…Toward this goal, various designs have been exploited, including carbon‐based materials, [ 310–312 ] metal meshes and nanowires, [ 313–315 ] and thin metal films. [ 92,202,316 ] Compared to other candidates, thin metal films exhibit unique advantages of simple structure and large‐scale manufacturing compatibility, and therefore, have been gaining increased attention in recent years. For example, Maniyara et al.…”

Section: Device Applicationsmentioning

confidence: 99%

“…By adding a monolayer graphene on the backside of the substrate, they were able to further increase the structure's RF absorption without scarifying much of its visible transparency. [ 316 ]…”

Section: Device Applicationsmentioning

confidence: 99%

Thin‐Metal‐Film‐Based Transparent Conductors: Material Preparation, Optical Design, and Device Applications

Zhang

Park

et al. 2020

Advanced Optical Materials

Self Cite

View full text Add to dashboard Cite

Transparent conductors are essential elements in an array of optoelectronic devices. The most commonly used transparent conductor – indium tin oxide (ITO) suffers from issues including poor mechanical flexibility, rising cost, and the need for annealing to achieve high conductivity. Consequently, there has been intensive research effort in developing ITO‐free transparent conductors over the recent years. This article gives a comprehensive review on the development of an important ITO‐free transparent conductor, that is based on thin metal films. It starts with the background knowledge of material selection for thin‐metal‐film‐based transparent conductors and then surveys various techniques to fabricate high‐quality thin metal films. Then, it introduces the spectroscopic ellipsometry method for characterizing thin metal films with high accuracy, and discusses the optical design procedure for optimizing transmittance through thin‐metal‐film‐based conductors. The review also summarizes diverse applications of thin‐metal‐film‐based transparent conductors, ranging from solar cells and organic light emitting diodes, to optical spectrum filters, low‐emissivity windows, and transparent electromagnetic interference coatings.

show abstract

Transparent Perfect Microwave Absorber Employing Asymmetric Resonance Cavity

Cited by 46 publications

References 62 publications

Design of an Optical Transparent Absorber and Defect Diagnostics Analysis Based on Near-Field Measurement

Design of an Optical Transparent Absorber and Defect Diagnostics Analysis Based on Near-Field Measurement

Ultra-light MXene aerogel/wood-derived porous carbon composites with wall-like “mortar/brick” structures for electromagnetic interference shielding

Thin‐Metal‐Film‐Based Transparent Conductors: Material Preparation, Optical Design, and Device Applications

Contact Info

Product

Resources

About