多波段兼容隐身用光子晶体研究进展
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摘要
光子晶体是由介电常数不同的几种材料组成的一种功能材料。频率处于光子晶体禁带范围内的电磁波在光子晶体中不能传播,表现出高反射的特性;而频率处于光子晶体通带范围内的电磁波则会透过光子晶体,表现出高透射的特性。电磁波传播可以通过光子晶体中缺陷的人工构造来控制。为理清多波段兼容隐身光子晶体材料进一步发展所面临的问题和机遇,对光子晶体在红外多波段隐身、激光/红外兼容隐身、雷达/红外兼容隐身、可见光/红外兼容隐身、多波段兼容隐身5个方面的研究进展进行了总结,并对新一代光子晶体兼容隐身技术的发展进行了展望。
Photonic crystal is a kind of functional material composed of various materials with different permittivity. The electromagnetic wave with frequency in the forbidden band of photonic crystal can't propagate in photonic crystal,which shows a high reflection characteristic. The electromagnetic waves in the frequency range of photonic crystal pass through the photonic crystal,which shows a high transmission characteristic,and the propagation of electromagnetic waves can be controlled by artificial construction of defects in the photonic crystal. In order to clarify the problems and opportunities for the further development of multiband compatible stealth photonic crystal materials,the research progresses on photonic crystals in multiband infrared stealth,laser/infrared compatible stealth,radar/infrared compatible stealth,and visible/infrared compatible stealth are reviewed,and the development of a new generation of photonic crystal compatible stealth technology is prospected.
Photonic crystal is a kind of functional material composed of various materials with different permittivity. The electromagnetic wave with frequency in the forbidden band of photonic crystal can't propagate in photonic crystal,which shows a high reflection characteristic. The electromagnetic waves in the frequency range of photonic crystal pass through the photonic crystal,which shows a high transmission characteristic,and the propagation of electromagnetic waves can be controlled by artificial construction of defects in the photonic crystal. In order to clarify the problems and opportunities for the further development of multiband compatible stealth photonic crystal materials,the research progresses on photonic crystals in multiband infrared stealth,laser/infrared compatible stealth,radar/infrared compatible stealth,and visible/infrared compatible stealth are reviewed,and the development of a new generation of photonic crystal compatible stealth technology is prospected.
引文
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