Tantalum Selenide Micro-Wafer Terahertz Emitter

Pub Date : 2023-11-23 DOI:10.1007/s10946-023-10161-7

Chuanxiang Ye, Jintao Wang

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引用次数: 0

Abstract

Terahertz waves possess distinct characteristics, including such as transience, coherence, low energy, penetration, and fingerprint spectroscopy, which render them well-suited for a diverse range of applications in security inspection, nondestructive testing, and environmental detection. However, the efficiency of terahertz wave generation remains constrained by the terahertz source. To address this limitation and minimize losses in the generation process, the selection of band-gap-free semi-metallic materials, as terahertz radiation sources, is of utmost importance. We successfully fabricate TaSe₂ micro-wafer measuring 1×0.5 μm. By employing optical pumping at a wavelength of 1040 nm and a pulse duration of 150 fs, we achieve a terahertz output of nearly 0.005 μW. This output surpasses the terahertz generation efficiency of GaP crystals by approximately 20% under the same power density. Furthermore, we conduct investigations into the impact of incidence and optical polarization on terahertz wave generation. TaSe₂ exhibits suitability for high-efficiency, micro–nano-scale terahertz wave generation applications, such as on-chip terahertz systems and micro–nano terahertz sources.

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硒化钽微晶片太赫兹发射器

太赫兹波具有不同的特性，包括瞬态、相干性、低能量、穿透性和指纹光谱，这使得它们非常适合在安全检查、无损检测和环境检测中的各种应用。然而，太赫兹波产生的效率仍然受到太赫兹源的限制。为了解决这一限制并最大限度地减少产生过程中的损耗，选择无带隙的半金属材料作为太赫兹辐射源至关重要。成功制备了尺寸为1×0.5 μm的TaSe2微晶片。利用波长为1040 nm、脉冲持续时间为150 fs的光泵浦，我们实现了近0.005 μW的太赫兹输出。在相同功率密度下，该输出比GaP晶体的太赫兹产生效率高出约20%。此外，我们还研究了入射光偏振对太赫兹波产生的影响。TaSe2显示出高效，微纳米级太赫兹波产生应用的适用性，如片上太赫兹系统和微纳米太赫兹源。

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