Litcius/Paper detail

THz Near-Field Imaging of Extreme Subwavelength Metal Structures

Xinzhong Chen, Xiao Liu, Xiangdong Guo, Shu Chen, Hai Hu, Elizaveta Nikulina, Xinlin Ye, Ziheng Yao, Hans A. Bechtel, Michael C. Martin, G. L. Carr, Qing Dai, Songlin Zhuang, Qing Hu, Yiming Zhu, Rainer Hillenbrand, Mengkun Liu, Guanjun You

2020ACS Photonics88 citationsDOIOpen Access PDF

Abstract

Modern scattering-type scanning near-field optical microscopy (s-SNOM) has become an indispensable tool in material research. However, as the s-SNOM technique marches into the far-infrared (IR) and terahertz (THz) regimes, emerging experiments sometimes produce puzzling results. For example, “anomalies” in the near-field optical contrast have been widely reported. In this Letter, we systematically investigate a series of extreme subwavelength metallic nanostructures via s-SNOM near-field imaging in the GHz to THz frequency range. We find that the near-field material contrast is greatly impacted by the lateral size of the nanostructure, while the spatial resolution is practically independent of it. The contrast is also strongly affected by the connectivity of the metallic structures to a larger metallic “ground plane”. The observed effect can be largely explained by a quasi-electrostatic analysis. We also compare the THz s-SNOM results to those of the mid-IR regime, where the size-dependence becomes significant only for smaller structures. Our results reveal that the quantitative analysis of the near-field optical material contrasts in the long-wavelength regime requires a careful assessment of the size and configuration of metallic (optically conductive) structures.

Topics & Concepts

Terahertz radiationNear-field scanning optical microscopeMaterials scienceOpticsNear and far fieldWavelengthNanostructureField (mathematics)Optical microscopeImage resolutionOptoelectronicsPhysicsNanotechnologyScanning electron microscopePure mathematicsMathematicsNear-Field Optical MicroscopySemiconductor Quantum Structures and DevicesPlasmonic and Surface Plasmon Research