OPTICAL METAMATERIALS AND SUPER-RESOLUTION IMAGING

E. Leong, Hong Liu, Y. Liu, J. Teng
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Abstract

Metamaterials are specially designed periodic structures (a ) that give rise to extraordinary optical properties that no natural materials can possess. It can have extremely large refractive index or a negative refractive index over a frequency band. The refractive index, n, determines how light travels in a medium and is related to the permittivity, ", and permeability, , by the relation n 1⁄4 ð" Þ1=2. It was ̄rst pointed out by Veselago that if " < 0 and < 0, then n becomes negative. Nevertheless, there are no natural materials that possess negative permeability, though metals possess negative permittivity at subplasma frequency. However it was Pendry's suggestion that negative refraction would make a perfect lens that drawn worldwide interests in this ̄eld. 5 Besides subwavelength di®raction limited imaging, metamaterials have also found applications in areas such as wideband directive antennas, band-stop ̄lters, radar absorbers, broadband phase shifters, cloaking and far̄eld optical microscopy. These can be achieved by engineering the propagation of light in the structure. This list of potential applications is non-exhaustive asmore concentrated e®orts are currently ongoing all over the world to design new structures and improve on old ones. The beauty of using metamaterial structures in devices is that the design can be made much smaller with improved performances, or at least comparable performances with conventionally established techniques. Ernest Abbe (184
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光学超材料和超分辨率成像
超材料是一种特殊设计的周期性结构(a),它能产生任何天然材料都无法拥有的非凡光学特性。它可以有极大的折射率或负折射率在一个频带。折射率n决定了光在介质中的传播方式,并与介电常数和磁导率有关,关系为n 1⁄4 ð Þ1=2。首先由Veselago指出,如果< 0且< 0,则n为负。然而,没有天然材料具有负磁导率,尽管金属在亚等离子体频率具有负介电常数。然而,彭德里的建议是负折射可以制造出完美的透镜,这引起了全世界对这一领域的兴趣。除了亚波长反应受限成像,超材料还在宽带定向天线、带阻器、雷达吸收器、宽带移相器、隐形和远场光学显微镜等领域得到了应用。这些可以通过设计光在结构中的传播来实现。这个潜在应用的列表并非详尽无遗,因为目前世界各地正在进行更集中的研究,以设计新结构并改进旧结构。在设备中使用超材料结构的美妙之处在于,设计可以做得更小,性能更好,或者至少可以与传统技术相媲美。欧内斯特·阿贝(184岁
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