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表面等离子体激元透镜(plasmonic lens, PL)是一种通过激发和操控表面等离子体激元 (SPPs), 突破衍射极限, 实现亚波长紧聚焦的纳米光子器件. 如何实现高效率的紧聚焦及调控, 一直是研究PL的重点. 如果选取电矢量沿径向振动的径向偏振光作为PL的入射光, 可从各个方向激发SPPs, 提高紧聚焦的能量效率. 本文提出了一种在径向偏振光激发下的长焦深、长焦距、亚波长紧聚焦的表面等离子体激元透镜, 该透镜由中心T 形微孔、阶梯形同心环和同心环结构组成. 本文首先利用有限元方法数值分析了中心微孔-同心环结构透镜的聚焦特性, 结果显示径向偏振光由底部入射可高效激发SPPs, 并且中心微孔透射光与散射至自由空间的SPPs由于多光束干涉形成了紧聚焦. 为进一步压缩焦斑、增加焦距、加深焦深、改善透镜聚焦特性, 本文引入中心T形微孔-阶梯形同心环结构, 从而对阶梯表面的SPPs同时提供了相位调制和传播方向的控制. 经过参数优化, 该透镜结构实现了光斑焦深、半高宽、焦距分别是入射光波长的2.5倍、0.388 倍、3.22倍的亚波长紧聚焦; 而且该透镜具有结构紧凑、尺寸小、易于集成的优点, 满足了纳米光子学对于器件微型化和高度集成化的要求. 该研究结果在纳米光子集成、近场光学成像与探测、纳米光刻等相关领域具有潜在的应用价值. 相似文献
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基于金属表面等离子激元控制光束的新进展 总被引:2,自引:0,他引:2
表面等离子激元(Surface plasmon polaritons,SPPs)是一种在金属-介质界面上激发并耦合电荷密度起伏的电磁振荡,具有近场增强、表面受限、短波长等特性,在纳米光子学的研究中扮演着重要角色。近年来表面等离子光学和基于SPPs的纳米光子器件的研究引起了国际上科学家们的广泛关注。讨论了SPPs的基本原理和在亚波长结构下的光学特性,介绍了基于亚波长金属结构的表面等离子激元在空间光束准直与聚焦、平面内光束聚焦与传导和在近场纳米光束的控制等方面的研究情况,以及在纳米光子学器件中的潜在应用。 相似文献
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利用表面等离激元短波长和近场增强效应的特性,用多束P偏振态相干光激发表面等离激元(SPPs),并优化干涉光刻的曝光参数,可获得高分辨率、高对比度周期性纳米结构.阐述了多束SPPs干涉法制备纳米光子晶体的原理,并得到了干涉场强度分布随光束增加的关系.随着干涉SPPs数目的增加,干涉场会复杂变化,对此进行了计算机模拟.模拟了三束SPPs和六束SPPs干涉的强度分布,并分析了调制技术干涉曝光结果,该方法适合光电子器件中大范围亚波长的周期性孔阵或点阵结构的制作以及纳米量级光子晶体的的制作,并可以有效降低制作成本. 相似文献
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使用近场光学显微术(scanning near-field optical microscopy, SNOM)研究了ZnO亚微米线端面出射性质,不同空间形貌Ⅱ-Ⅵ族半导体荧光器件光波导特性,二维光子晶体、准晶光子晶体对LED的出射增强作用以及表面等离激元(surface plasmon polariton, SPP)与半导体纳米荧光器件的相互作用,对纳米集成光路中的光源、光波导、光增强三个重要问题做了实验和理论上的分析.研究发现半导体微纳米线端面出射光束的质量与样品的直径有密切关系.通过合理地设计其直径和
关键词:
纳米集成光路
扫描近场光学显微术
光波导
光增强 相似文献
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全光二极管是集成光子回路上最基本的光子器件,如何有效增强全光二极管的单向透射性,提高消光比一直是学者们研究的重点.当前,利用表面等离极化激元(surface plasmon polaritons,SPPs)和复合衍射衰逝波(composite diffracted evanescent wave,CDEW)的亚波长金属微纳结构构建全光二极管器件还鲜有研究.因此,开发出一种可调制的全光二极管,对未来制备复杂的光子回路具有重要意义.本文提出了一种基于SPPs-CDEW混合模式设计全光二极管的方法和结构,该结构结合纳米缝中的类法布里-珀罗共振效应,利用结构参数对SPPs进行调控,实现了光束单向透过的功能.首先,利用理论推导和有限元算法分析了单缝-对称双凹槽纳米结构的透射增强现象,提出了透射增强和削弱的物理机理.其次,计算出规约化透射率随单狭缝和凹槽对之间距离变化的远场透射谱,给出的理论和数值计算结果符合得很好.最后,通过此透射谱精确确定凹槽的位置和数量,得出上表面对称分布五对增强透射凹槽、下表面六对抑制透射凹槽的最优全光二极管结构,有效增强了全光二极管的单向透射性,提高了消光比,最大消光比可以达到38.3 dB,即正向透射率是反向透射率的6761倍,比已有文献提高了14.6 dB,并在850 nm左右有70 nm宽的工作波长带宽(20 dB).本文提出的光二极管结构简单,宽带宽工作,易于集成,耦合效率高,研究结果对光学信号传输、集成光回路、超分辨率光刻等相关领域具有潜在的应用价值. 相似文献
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从电动力学到量子电动力学:纳米光电子器件 总被引:1,自引:0,他引:1
纳米尺度下的光电器件的研制与米、毫米、微米尺度下电子器件或光学器件的研制在基本原理与制造技术上有本质的不同。必须采用量子电动力学和介观物理作为基本原理。在量子电动力学中,光子与电子可以相互转化,光子也可以储存在“空腔”中。光一电转换或光一电一光的转换甚至可以在远小于一个光波的尺度内实现(如100nm以下)。基于大量最新现象发现的启示与推动,产生了一种全新的光予技术:纳米光子技术。在这种全新的纳光子技术中,人们将光子电子的输运与转化联合起来进行考虑,非线性光学获得了长足的发展。微电子技术和概念被大量地推广应用于纳光子技术开发。创新型元件如集成激光器、30dB光放大器、效率为30%的1.55μm滤波器等层出不穷地涌现。纳米技术的研发为信息储存、输运和处理开辟了新的天地。进入21世纪,纳米光子技术研究日新月异。在摩尔经验规律的指导下,不断发展的微电子工业的制造精度已进入100nm领域。大规模应用纳米电子、纳米光子技术的时代已经来临。一些新型的光通讯线路已开始应用纳米光子器件。对公众而言,用于照明的LED只是一个应用实例。报告将结合法国国家纳米研究平台的研发成果来阐述纳米光子学的原理和纳米光子器件发展的趋势。 相似文献
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使用近场光学显微术(scanning near-field optical microscopy, SNOM)研究了ZnO亚微米线端面出射性质,不同空间形貌Ⅱ-Ⅵ族半导体荧光器件光波导特性,二维光子晶体、准晶光子晶体对LED的出射增强作用以及表面等离激元(surface plasmon polariton, SPP)与半导体纳米荧光器件的相互作用,对纳米集成光路中的光源、光波导、光增强三个重要问题做了实验和理论上的分析.研究发现半导体微纳米线端面出射光束的质量与样品的直径有密切关系.通过合理地设计其直径和 相似文献
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Based on finite-difference time-domain simulation of the propagation characteristics of surface plasmon polaritons (SPPs) in optical circuits made from metal gap waveguides (MGWs) with nanometric gap widths, we theoretically demonstrate that two structures that consist of splitting and recombining MGWs and of coupling MGWs can be used as nanoscale Mach-Zehnder interferometers. MGW arrays show capabilities for array imaging and for controlling the flow of SPPs. Other potential applications of coupling MGWs, as SPP switches, directional couplers, and even as a nanoscale counterpart for observing linear and nonlinear dynamic behavior of electromagnetic fields, are also predicted and discussed. Our results point to an interesting way to manipulate optical signals and provide efficient sensing in nanophotonic architectures. 相似文献
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Naoya Tate Makoto Naruse Yang Liu Tadashi Kawazoe Takashi Yatsui Motoichi Ohtsu 《Applied physics. B, Lasers and optics》2013,112(4):587-592
We have previously demonstrated a novel technique for autonomously forming a nanophotonic droplet, which is micro-scale spherical polymer structure that contains paired heterogeneous nanometric components. The sort-selectivity and alignment accuracy of the nanometric components in each nanophotonic droplet, and the related homogeneity of the optical function, are due to a characteristic pairing process based on a phonon-assisted photo-curing method. The proposed method requires irradiating a mixture of components with light to induce optical near-field interactions between each component, and subsequent processes based on these interactions. The pairing yield of components via the interactions is considered to mainly depend on the frequency of their encounters and the size-resonance effect between encountered components. In this paper, we model these two factors by individual stochastic procedures and construct a numerical model to describe the pairing process. Agreement between the results of numerical and experimental demonstrations shows the validity of our stochastic modeling. 相似文献
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X. Cui L. Dong W. Zhang W. Wu Y. Tang D. Erni 《Applied physics. B, Lasers and optics》2010,101(3):601-609
Motivated by the fabrication potential of multi-walled carbon nanotube structures, we numerically investigated a paired structure
consisting of two metallic spheres each grown on one end of a multi-walled nanotube. The paired two-segmented structure is
capable to convert free-space radiation into an intense near-field, and, hence, acting as an optical antenna. Vice versa the
presence of the two nanotubes enable a current source at the antenna feed to more efficiently energy into the radiation modes,
resulting e.g. in correspondingly altered luminescence lifetimes when an excited single molecule is placed in the feed point.
Furthermore, the structure represents a mean to localize light on a sub-wavelength scale within different materials, which
is interesting in the context of a fabrication technology for integrated nanophotonic components with different material combinations.
The optical properties of the nano-antenna are analyzed by means of numerical simulations using the finite element method.
Our investigations have revealed that the field enhancement, the resonances, and the radiation patterns can be easily tuned
since all these quantities strongly depend on the size of the nanotubes and the metallic spheres, as well as on their material
properties The structure we propose here carries a great potential for bio-sensing, for tip-enhanced spectroscopy applications,
and for interfacing integrated photonic nano circuits. 相似文献
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We propose and demonstrate a bi-wavelength two dimensional (2D) waveguide grating coupler on silicon-on-insulator which has efficient coupling of optical light with two-wavelength bands independently between standard optical single mode fibers and nanophotonic waveguides. The details of design are described and the measurement results as well as system performance are experimentally characterized. The bi-wavelength grating coupler can be used as wavelength-division-multiplexing (WDM) splitter/combiner for monolithically silicon integrated transceivers, potentially meeting the low cost requirements for future WDM passive optical network (PON). 相似文献
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An optical effect analogous to electromagnetically induced transparency (EIT) is observed in nanoscale plasmonic resonator systems. The system consists of a slot cavity as well as plasmonic bus and resonant waveguides, where the phase-matching condition of the resonant waveguide is tunable for the generation of an obvious EIT-like coupled resonator-induced transparency effect. A dynamic theory is utilized to exactly analyze the influence of physical parameters on transmission characteristics. The transparency effect induced by coupled resonance may have potential applications for nanoscale optical switching, nanolaser, and slow-light devices in highly integrated optical circuits. 相似文献
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Naoya Tate Yang Liu Tadashi Kawazoe Makoto Naruse Takashi Yatsui Motoichi Ohtsu 《Applied physics. B, Lasers and optics》2013,110(3):293-297
Although recent advances in fabrication technologies have allowed the realization of highly accurate nanometric devices and systems, most approaches still lack uniformity and mass-production capability sufficient for practical use. We have previously demonstrated a novel technique for autonomously coupling heterogeneous quantum dots to induce particular optical responses based on a simple phonon-assisted photocuring method in which a mixture of quantum dots and photocurable polymer is irradiated with light. The cured polymer sequentially encapsulates coupled quantum dots, forming what we call a nanophotonic droplet. Recently, we found that each quantum dot in the mixture is preferably coupled with other quantum dots of similar size due to a size resonance effect of the optical near-field interactions between them. Moreover, every nanophotonic droplet is likely to contain the same number of coupled quantum dots. In this paper, we describe the basic mechanisms of autonomously fabricating nanophotonic droplets, and we examine the size- and number-selectivity of the quantum dots during their coupling process. The results from experiments show the uniformity of the optical properties of mass-produced nanophotonic droplets, revealed by emission from the contained coupled quantum dots, due to the fundamental characteristics of our method. 相似文献
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全光开关是全光网络和数字光信息处理的基本器件,该器件主要基于非线性光学原理.自激光发明以来,对该器件的研究已历时半个世纪.虽然全光开关的基础研究十分活跃,研究成果丰硕,但是至今尚未做出实用器件.文章分析了全光开关面临的困难,指出只有在极小的时空条件下,也就是采用飞秒激光驱动的纳米尺寸器件,才有可能研制出低开关功率、高开关速度、低插入损耗的实用的全光开关器件.文章简要介绍了近10年来纳米全光开关的研究成果,包括纳米尺寸干涉仪开关(空间开关)、量子限制光双稳触发器(时间开关)、半导体光放大器的波长转换器(波长开关)、光子晶体带隙移动开关和表面等离子体激元开关(强度开关)等5类16种典型的纳米全光开关器件. 相似文献
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Graphene plasmons have become promising candidates for deep-subwavelength nanoscale optical devices due to their strong field confinement and low damping. Among these nanoscale optical devices, band-pass filter for wavelength selection and noise filtering are key devices in an integrated optical circuit. However, plasmonic filters are still oversized because large resonant cavities are needed to perform frequency selection. Here, an ultra-compact filter integrated in a graphene plasmonic waveguide was designed, where a rectangular resonant cavity is inside a graphene nanoribbon waveguide. The properties of the filter were studied using the finite-difference time-domain method and demonstrated using the analytical model. The results demonstrate the band-pass filter has a high quality factor(20.36) and electrically tunable frequency response. The working frequency of the filter could also be tuned by modifying the cavity size. Our work provides a feasible structure for a graphene plasmonic nano-filter for future use in integrated optical circuits. 相似文献
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We developed and are presenting a graphene-based nanophotonic Mach–Zehnder Interferometer (MZI), which can operate as a signal follower, switch and splitter and as a multiplexer/demultiplexer. Due to the excellent electrical/optical parameters inherent to the graphene, we showed that the device we are presenting can works in several different ways, which can not be supported by MZI based on conventional materials. It is worth mentioning that the operations of the device we have developed take into account the electrical/optical parameters of the graphene, which provide greater versatility and efficiency compared to the MZIs manufactured with conventional materials. In addition, these parameters can be controlled via, for example, gate voltage, so that many operations can be performed in parallel, which is also not possible through the use of conventional materials. Due to its manometric dimensions, this MZI can be integrated within photonic integrated circuits, so that we can use this device in dense wavelength division multiplexing optical communications. 相似文献