Gold Plasmonic(金等离子)研究综述
Gold Plasmonic 金等离子 - Numerical results indicate that the proposed temperature sensor shows the possible maximum wavelength/temperature sensitivity of 1450 pm/°C for graphene plasmonic and 2500 pm/°C for gold plasmonic, calculated using wavelength interrogation method. [1]数值结果表明,使用波长询问法计算,所提出的温度传感器显示出石墨烯等离子体的可能最大波长/温度灵敏度为 1450 pm/°C,金等离子体的最大波长/温度灵敏度为 2500 pm/°C。 [1]
gold plasmonic nanostructure
Here, we propose a design of III–V nanowires on silicon (100) substrates, which are self-assembled with gold plasmonic nanostructures, as a key building block for efficient and functional photodetectors on silicon. [1] We demonstrate nanocrescent gold plasmonic nanostructures that substantially enhance the absorption of long-wavelength photons whose energy is greatly below the tunneling barrier and significantly boost the electron thermalization in graphene. [2] This paper explores the enhancement of Raman signals using individual nano-plasmonic structures and demonstrates the possibility to obtain controlled gold plasmonic nanostructures by atomic force microscopy (AFM) manipulation under a confocal Raman device. [3]在这里,我们提出了一种在硅 (100) 衬底上设计 III-V 纳米线,它与金等离子体纳米结构自组装,作为硅上高效和功能光电探测器的关键组成部分。 [1] 我们展示了纳米新月形金等离子体纳米结构,它显着增强了长波长光子的吸收,其能量大大低于隧道势垒,并显着提高了石墨烯中的电子热化。 [2] 本文探讨了使用单个纳米等离子体结构来增强拉曼信号,并展示了在共焦拉曼装置下通过原子力显微镜 (AFM) 操作获得受控金等离子体纳米结构的可能性。 [3]