使用千兆赫掺镱双梳激光器的太赫兹-TDS:噪声分析与缓解策略。

Applied optics Pub Date : 2024-05-20 DOI:10.1364/AO.522802
Benjamin Willenberg, Christopher R Phillips, Justinas Pupeikis, Sandro L Camenzind, Lars Liebermeister, Robert B Kohlhass, Björn Globisch, Ursula Keller
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摘要

我们利用基于单个空间多路复用激光腔的低噪声双频梳状激光器研究了太赫兹时域光谱学。该激光腔包括一个反射双棱镜,可产生一对重复率略有不同、噪声特性高度相关的模型锁定输出脉冲串。这两个脉冲序列用于产生太赫兹波,并通过等效时间采样进行探测。该激光器基于 Yb:CALGO,工作在 1.18 GHz 的标称重复率下,在 1057 nm 波长附近以 77 fs 脉冲产生每个梳状输出 110 mW。我们使用掺铁的光电导天线进行了太赫兹测量,据我们所知,这是首次用千兆赫兹 1 µm 激光器操作这些设备,并获得了与 1.55 µm 和 80 MHz 参考测量结果大致相同的太赫兹信号电流。我们研究了激光器的定时噪声特性对太赫兹测量的影响,结果表明激光器的定时抖动可以通过中心波长随功率的变化得到定量解释。我们展示了通过简单的泵浦功率稳定来降低噪声,并通过共享泵浦和共享腔体结构的组合来抑制高达 20 dB 的噪声。激光器的超低噪声特性使我们能够对重复频率从 1 kHz 到 22 kHz 的太赫兹波形进行平均处理,从而在 1 kHz 下工作并平均处理 2 s 时获得 55 dB 的动态范围。我们的研究表明,所获得的动态范围是有竞争力的,可以通过考虑测量的光延迟范围、积分时间以及跨阻抗放大噪声的测量带宽依赖性来很好地解释。这些结果将有助于利用低噪声千兆赫双梳激光器实现高分辨率 THz-TDS 的新方法。
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THz-TDS with gigahertz Yb-based dual-comb lasers: noise analysis and mitigation strategies.

We investigate terahertz time-domain spectroscopy using a low-noise dual-frequency-comb laser based on a single spatially multiplexed laser cavity. The laser cavity includes a reflective biprism, which enables generation of a pair of modelocked output pulse trains with slightly different repetition rates and highly correlated noise characteristics. These two pulse trains are used to generate the THz waves and detect them by equivalent time sampling. The laser is based on Yb:CALGO, operates at a nominal repetition rate of 1.18 GHz, and produces 110 mW per comb with 77 fs pulses around 1057 nm. We perform THz measurements with Fe-doped photoconductive antennas, operating these devices with gigahertz 1 µm lasers for the first time, to our knowledge, and obtain THz signal currents approximately as strong as those from reference measurements at 1.55 µm and 80 MHz. We investigate the influence of the laser's timing noise properties on THz measurements, showing that the laser's timing jitter is quantitatively explained by power-dependent shifts in center wavelength. We demonstrate reduction in noise by simple stabilization of the pump power and show up to 20 dB suppression in noise by the combination of shared pumping and shared cavity architecture. The laser's ultra-low-noise properties enable averaging of the THz waveform for repetition rate differences from 1 kHz to 22 kHz, resulting in a dynamic range of 55 dB when operating at 1 kHz and averaging for 2 s. We show that the obtained dynamic range is competitive and can be well explained by accounting for the measured optical delay range, integration time, as well as the measurement bandwidth dependence of the noise from transimpedance amplification. These results will help enable a new approach to high-resolution THz-TDS enabled by low-noise gigahertz dual-comb lasers.

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