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双平行圆柱形MDM纳米棒等离子体波导的传输特性分析 总被引:1,自引:0,他引:1
设计了一种由双平行圆柱形纳米棒构成的金属-介质-金属(MDM)型等离子体波导,采用时域有限差分方法(FDTD)分析了波导结构的传输特性。当光波垂直主轴入射时,电磁场被很好地局限在两纳米棒所形成的中间区域以及介质层中,从而在该波导中能够有效地耦合电磁场能量。在工作波长为1 550 nm的情况下,随着内层金属芯半径的增大,有效折射率减小,传播距离增大;而中间介质层厚度增大时,有效折射率增大,传播距离减小。当外层金属壳厚为20 nm时,电场可以很好地被限制在纳米棒的介质层内。上述结果表明:通过调整波导结构的几何参数可以显著提高金属纳米棒的场限制,降低波导本身的损耗, 使波导的有效折射率和传播长度达到最优化。这种等离子体波导能够实现亚波长的光限制,可以应用于光子器件集成和传感器领域。 相似文献
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为了深入探讨带状波导的表面等离子激元透射特性,采用衍射光栅耦合方式实现表面等离子激元激发,通过改变金属薄膜厚度和入射光角度,得到薄膜厚度、入射光角度与透射率的变化特性.结果表明:金属薄膜厚度的减少会导致透射带宽迅速降低,同时透射率也随之降低;而入射光角度的改变导致透射光效率的变化.这一研究对于半导体设备的纳米等离子激元耦合具有一定的意义. 相似文献
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Novel graphene enhancement nanolaser based on hybrid plasmonic waveguides at optical communication wavelength 下载免费PDF全文
Surface plasmon polariton(SPP) nanolaser, which can achieve an all-optical circuit, is a major research topic in the field of micro light source. In this study, we examine a novel SPP graphene nanolaser in an optoelectronic integration field.The proposed nanolaser consists of metallic silver, two-dimensional(2 D) graphene and high refractive index semiconductor of indium gallium arsenide phosphorus. Compared with other metals, Ag can reduce the threshold and propagation loss.The SPP field, excited by coupling Ag and InGaAsP, can be enhanced by the 2 D material of graphene. In the proposed nanolaser, the maximum value of propagation loss is approximately 0.055 d B/μm, and the normalized mode area is constantly less than 0.05, and the best threshold can achieve 3380 cm~(-1) simultaneously. Meanwhile, the proposed nanolaser can be fabricated by conventional materials and work in optical communication(1550 nm), which can be easily achieved with current nanotechnology. It is also an important method that will be used to overcome the challenges of high speed,miniaturization, and integration in optoelectronic integrated technology. 相似文献
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冲击整形扩径工艺是修复油水井套管损坏的常用技术,根据冲击整形的施工工艺和波动理论,建立了套损局部位置处水泥环的损伤力学模型,以有限变形理论为基础,采用悬臂梁力学模型,分段研究了冲击整形时钻杆屈曲的平衡位形及对套管、水泥环产生的冲击力. 结合水泥环的应力状态, 根据脆性材料的Mazars损伤模型,建立了水泥环的损伤力学模型. 并分析了水泥环的损伤状态. 通过与现场测试结果对比,理论计算与实测结果误差在2.7%左右. 相似文献
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