Abstract
Nanostructures can induce light multireflection, enabling strong light absorption and efficient photocarrier generation. In this work, silicon nanostructures, including nanocylinders, nanotips, and nanoholes, were proposed as all-optical broadband THz modulators. The modulation properties of these modulators were simulated and compared with finite element method calculations. It is interesting to note that the light reflectance values from all nanostructure were greatly suppressed, showing values of 26.22%, 21.04%, and 0.63% for nanocylinder, nanohole, and nanotip structures, respectively, at 2 THz. The calculated results show that under 808 nm illumination light, the best modulation performance is achieved in the nanotip modulator, which displays a modulation depth of 91.63% with a pumping power of 60 mW/mm2 at 2 THz. However, under shorter illumination wavelengths, such as 532 nm, the modulation performance for all modulators deteriorates and the best performance is found with the nanohole-based modulator rather than the nanotip-based one. To further clarify the effects of the nanostructure and wavelength on the THz modulation, a graded index layer model was established and the simulation results were explained. This work may provide a further theoretical guide for the design of optically tunable broadband THz modulators.
Highlights
Terahertz (THz) radiation (0.1~10 THz) triggers a great number of intriguing and complex physical, biological, and chemical phenomena
The results show that the THz modulation depth of nanostructure-based modulators is larger than that of the bare silicon-based modulator
The photoconductivity values of bare silicon, nanocylinder, nanotip, and nanohole structures versus pumping power densities are shown in Figure 3, with the inset presenting the power absorption variation
Summary
Terahertz (THz) radiation (0.1~10 THz) triggers a great number of intriguing and complex physical, biological, and chemical phenomena. It possesses wide practical application prospects in communications, spectroscopy, and imaging [1,2,3,4,5,6,7]. The present THz modulators do not fully meet such requirements, hindering their application in THz imaging. High-resistivity (HR) silicon has been proven to be suitable for optically tunable THz modulations [8]. THz waves can be modulated by optically pumping silicon to form a temporary region with either high absorption or strong reflection [9]. Okada et al [10] and Xie et al [11] proposed silicon-based spatial THz modulators (STM), while
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