高等学校化学学报 ›› 2019, Vol. 40 ›› Issue (6): 1103.doi: 10.7503/cjcu20180627
黄智宇1, 陈宏辉1, 马文乐1, 黄毅1(), 朱丹2, 陈永胜1
收稿日期:
2018-09-11
出版日期:
2019-06-10
发布日期:
2019-04-04
作者简介:
联系人简介: 黄 毅, 男, 博士, 教授, 博士生导师, 主要从事电磁波吸波材料及智能材料研究. E-mail: 基金资助:
HUANG Zhiyu1, CHEN Honghui1, MA Wenle1, HUANG Yi1(), ZHU Dan2, CHEN Yongsheng1
Received:
2018-09-11
Online:
2019-06-10
Published:
2019-04-04
Supported by:
摘要:
阐述了太赫兹隐身和屏蔽性能分析的计算模型, 并对几种典型的太赫兹隐身和屏蔽材料进行了综述和介绍, 指出了当前研究存在的问题以及今后的发展方向.
中图分类号:
TrendMD:
黄智宇, 陈宏辉, 马文乐, 黄毅, 朱丹, 陈永胜. 太赫兹隐身及屏蔽材料研究进展. 高等学校化学学报, 2019, 40(6): 1103.
HUANG Zhiyu, CHEN Honghui, MA Wenle, HUANG Yi, ZHU Dan, CHEN Yongsheng. Research Progress on Terahertz Stealth and Shielding Materials†. Chem. J. Chinese Universities, 2019, 40(6): 1103.
Fig.3 Structures and terahertz stealth performance of GaAs/PI metamaterials(A,B)[11] and Si/SiO2 metamaterials with dielectric thickness from 0.4 μm to 1.2 μm(C,D)[12] (A, B) Copyright 2008, Optical Society of America; (C, D) copyright 2012, American Institute of Physics.
Fig.4 Structures and terahertz stealth performance of polarization insensitivity stealth metamaterials(A,B)[18] and wide-angle stealth metamaterials(C—E)[19] (A, B) Copyright 2009, American Physical Society; (C—E) copyright 2008, American Physical Society.
Fig.8 Terahertz reflectivity of graphene at different incident angles[23] Incident angle: (A) 15°; (B) 30°; (C) 45°; (D) 60°. Copyright 2016, Elsevier.
Materials | Measured band/THz | SATAP*/ (dB·g-1·cm3) | Maxim absorption/dB | Qualified bandwidth(%) | Reference |
---|---|---|---|---|---|
Graphene foam | 0.1—1.2 | 2.37×104 | 28.6 | 100 | [ |
Terahertz metamaterial | 0.1—3.0 | 6.81 | 14 | 44.83 | [ |
Terahertz metamaterial | 0.2—2.2 | 6.31 | 15.2 | 65 | [ |
Multi-layer terahertz metamaterial | 0.2—1.6 | 5.20 | 17 | 50 | [ |
Metamaterial absorber | 1.0—10.0 | 4.76 | 17 | 22.22 | [ |
PMMA/Graphite | 0.1—1.6 | 4.37 | 13 | 13.33 | [ |
Graphene metamaterial | 0—2.5 | 3.72 | 27 | 18 | [ |
Metamaterial absorber | 0.5—2.5 | 1.39 | 5.2 | N/A | [ |
SiO2/Al based metamaterial | 2.5—6.0 | 0.96 | 17 | 5.71 | [ |
Dual-band metamaterial | 0.3—3.5 | 0.94 | 15.2 | 3.75 | [ |
Multi-band metamaterial | 0.2—2.6 | 0.85 | 17 | 2.08 | [ |
Metal/graphene plasmons | 0—10.0 | 0.67 | 3 | N/A | [ |
BaTiO3/PMMA | 0.2—0.6 | N/A | 17 | 35 | [ |
Kapton-derived carbon | 0.3—0.5 | N/A | 2.8 | N/A | [ |
Graphene-based metamaterial absorbers | 1—4.5 | N/A | 15.2 | 71.43 | [ |
Terahertz metamaterial absorber | 1.0—7.0 | N/A | 14 | 13 | [ |
Terahertz metamaterial | 1.0—3.4 | N/A | 15.2 | 4.17 | [ |
Table 1 Terahertz stealth materials reported in open literatures
Materials | Measured band/THz | SATAP*/ (dB·g-1·cm3) | Maxim absorption/dB | Qualified bandwidth(%) | Reference |
---|---|---|---|---|---|
Graphene foam | 0.1—1.2 | 2.37×104 | 28.6 | 100 | [ |
Terahertz metamaterial | 0.1—3.0 | 6.81 | 14 | 44.83 | [ |
Terahertz metamaterial | 0.2—2.2 | 6.31 | 15.2 | 65 | [ |
Multi-layer terahertz metamaterial | 0.2—1.6 | 5.20 | 17 | 50 | [ |
Metamaterial absorber | 1.0—10.0 | 4.76 | 17 | 22.22 | [ |
PMMA/Graphite | 0.1—1.6 | 4.37 | 13 | 13.33 | [ |
Graphene metamaterial | 0—2.5 | 3.72 | 27 | 18 | [ |
Metamaterial absorber | 0.5—2.5 | 1.39 | 5.2 | N/A | [ |
SiO2/Al based metamaterial | 2.5—6.0 | 0.96 | 17 | 5.71 | [ |
Dual-band metamaterial | 0.3—3.5 | 0.94 | 15.2 | 3.75 | [ |
Multi-band metamaterial | 0.2—2.6 | 0.85 | 17 | 2.08 | [ |
Metal/graphene plasmons | 0—10.0 | 0.67 | 3 | N/A | [ |
BaTiO3/PMMA | 0.2—0.6 | N/A | 17 | 35 | [ |
Kapton-derived carbon | 0.3—0.5 | N/A | 2.8 | N/A | [ |
Graphene-based metamaterial absorbers | 1—4.5 | N/A | 15.2 | 71.43 | [ |
Terahertz metamaterial absorber | 1.0—7.0 | N/A | 14 | 13 | [ |
Terahertz metamaterial | 1.0—3.4 | N/A | 15.2 | 4.17 | [ |
Sample | Reflectance | Sample | Reflectance |
---|---|---|---|
380 μm Si(polished) | 0.30 | 150 μm VANTA | 0.18 |
40 μm VANTA | 0.46 | 1.5 μm VANTA | 0.01 |
Table 2 Summary of reflectance-measurement results at 394 μm wavelength[39]
Sample | Reflectance | Sample | Reflectance |
---|---|---|---|
380 μm Si(polished) | 0.30 | 150 μm VANTA | 0.18 |
40 μm VANTA | 0.46 | 1.5 μm VANTA | 0.01 |
Fig.12 Terahertz shielding performance CNF composites with different CNF content(A)[46] and different thicknesses(B)[47] at 0.57—0.63 THz (A) Copyright 2011, American Institute of Physics; (B) copyright 2012, American Institute of Physics.
Fig.13 Transmission performance of GO with different annealing temperatures(A) and thicknesses(B) at 0.2—1.0 THz[48] Copyright 2015, Royal Society of Chemistry.
Fig.15 3D representations of the EMI SE values of MGF-1500(2∶1)(A) and the simulated RL values of MGF(2∶1) with the same thickness of 2 mm and different annealing temperatures(B)[62] Copyright 2018, American Institute of Physics.
Material | Measured band/THz | SATSCa/ (dB· g-1·cm3) | Maximum shielding effectiveness/dB | Qualifid bandwidth(%) | Reference |
---|---|---|---|---|---|
Kapton-derived carbon | 0.22—0.5 | 54.5 | 90 | 100 | [ |
Graphite/PMMA | 0.1—1.6 | 42.4 | 50 | 100 | [ |
PAN/TPU | 0.2—1.2 | 38.2 | 58 | 100 | [ |
CNW/PMC | 0.57—0.63 | 36.4 | 48 | 100 | [ |
SWCNTs | 0.2—2.5 | 29.2 | 38 | 100 | [ |
CNF/PTFE/PVDF/PMMA | 0.57—0.63 | 25.4 | 32 | 100 | [ |
OLC/KBr | 12—230 | 17.8 | 40 | 100 | [ |
MWCNTs/PMMA | 0.1—4 | 16.9 | 40 | 83 | [ |
SWCNTs/PVA | 0.3—2.1 | 15.7 | 30 | 89 | [ |
MWCNTs | 0.4—2.2 | 13.9 | 30 | 100 | [ |
Graphene/SiO2 | 0.01—100 | 13.6 | 60 | 10 | [ |
DND/KBr | 110—230 | 8.9 | 20 | 100 | [ |
SWCNTs/PET | 0.1—1.2 | 3.6 | 4 | 0 | [ |
OLC/PMMA | 0.1—3 | 3.4 | 14 | 17 | [ |
RGO | 0.3—1.0 | 0.48 | 3.8 | N/Ab | [ |
Few-layer graphene | 0.6—600 | N/Ab | 0.9 | N/Ab | [ |
Epitaxial graphene on SiC | 1.5—750 | N/Ab | 2.2 | N/Ab | [ |
Monolayer graphene | 0.57—0.63 | N/Ab | 1 | N/Ab | [ |
Graphene insulator stacks | 0.03—10.2 | N/Ab | 16 | 25 | [ |
Table 3 Terahertz shielding materials reported in open literatures
Material | Measured band/THz | SATSCa/ (dB· g-1·cm3) | Maximum shielding effectiveness/dB | Qualifid bandwidth(%) | Reference |
---|---|---|---|---|---|
Kapton-derived carbon | 0.22—0.5 | 54.5 | 90 | 100 | [ |
Graphite/PMMA | 0.1—1.6 | 42.4 | 50 | 100 | [ |
PAN/TPU | 0.2—1.2 | 38.2 | 58 | 100 | [ |
CNW/PMC | 0.57—0.63 | 36.4 | 48 | 100 | [ |
SWCNTs | 0.2—2.5 | 29.2 | 38 | 100 | [ |
CNF/PTFE/PVDF/PMMA | 0.57—0.63 | 25.4 | 32 | 100 | [ |
OLC/KBr | 12—230 | 17.8 | 40 | 100 | [ |
MWCNTs/PMMA | 0.1—4 | 16.9 | 40 | 83 | [ |
SWCNTs/PVA | 0.3—2.1 | 15.7 | 30 | 89 | [ |
MWCNTs | 0.4—2.2 | 13.9 | 30 | 100 | [ |
Graphene/SiO2 | 0.01—100 | 13.6 | 60 | 10 | [ |
DND/KBr | 110—230 | 8.9 | 20 | 100 | [ |
SWCNTs/PET | 0.1—1.2 | 3.6 | 4 | 0 | [ |
OLC/PMMA | 0.1—3 | 3.4 | 14 | 17 | [ |
RGO | 0.3—1.0 | 0.48 | 3.8 | N/Ab | [ |
Few-layer graphene | 0.6—600 | N/Ab | 0.9 | N/Ab | [ |
Epitaxial graphene on SiC | 1.5—750 | N/Ab | 2.2 | N/Ab | [ |
Monolayer graphene | 0.57—0.63 | N/Ab | 1 | N/Ab | [ |
Graphene insulator stacks | 0.03—10.2 | N/Ab | 16 | 25 | [ |
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