Dmitrii Konnov, Andrey Muraviev, Sergey Vasilyev, Konstantin Vodopyanov
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引用次数: 0
摘要
采用少光周期探测脉冲的超宽带电光采样是一种检测高动态范围、近红外光频率电场幅值的灵敏技术。通过将该方法与双频梳光谱学相结合,并使用一种新型的超快激光器,我们在1.5-45太赫兹(6.6-200 μm)的频率范围内进行了高分辨率,80 MHz/0.0027 cm - 1 (10 MHz/0.0003 cm - 1与光谱交错)的光谱测量,排除了4.5-9太赫兹晶格共振的强吸收Reststrahlen带,瞬时光谱覆盖超过一个倍频程(例如9-22 μm)。我们使用克尔透镜锁模固态Cr:ZnS (2.35 μm)激光器的一对互相干梳作为驱动源。其中一个梳通过脉冲内差频产生频率降频,产生长波“传感”梳,而第二个梳的频率翻倍,产生近红外“探头”梳,用于电光采样(EOS)。我们的双梳系统的低强度和相位噪声允许以69 Hz的视频速率捕获光谱中红外部分的大量光谱信息(20万条梳模式分辨谱线,间隔为80 MHz),信噪比受到近红外EOS平衡检测系统的散点噪声的限制。我们对低压气体乙醇、异戊二烯和二甲基硫化物的双梳状光谱测量揭示了以前从未探索过的多普勒限制光谱特征。
High-resolution frequency-comb spectroscopy with electro-optic sampling and instantaneous octave-wide coverage across mid-IR to THz at a video rate
Ultrabroadband electro-optic sampling using few-optical-cycle probing pulses is a sensitive technique to detect electric field amplitudes with a high dynamic range and up to near-infrared optical frequencies. By combining this method with dual-frequency-comb spectroscopy and using a new class of ultrafast lasers, we perform high-resolution, 80 MHz/0.0027 cm−1 (10 MHz/0.0003 cm−1 with spectral interleaving), spectroscopic measurements in the frequency range 1.5–45 THz (6.6–200 µm), excluding the strongly absorbing Reststrahlen band of lattice resonances at 4.5–9 THz, with an instantaneous spectral coverage exceeding an octave (e.g., 9–22 μm). As a driving source, we use a pair of mutually coherent combs from Kerr-lens mode-locked solid-state Cr:ZnS (2.35 μm) lasers. One of the combs is frequency downconverted via intrapulse difference frequency generation to produce a longwave “sensing” comb, while the second comb is frequency doubled to produce a near-IR “probe” comb for electro-optic sampling (EOS). The low intensity and phase noise of our dual-comb system allow for capturing a large amount of spectral information (200 000 comb-mode-resolved spectral lines spaced by 80 MHz) in the mid-IR portion of the spectrum at a video rate of 69 Hz, with the signal-to-noise ratio limited by the shot noise of the near-IR EOS balanced detection system. Our dual-comb spectroscopy measurements with low-pressure gaseous ethanol, isoprene, and dimethyl sulfide reveal Doppler-limited spectroscopic signatures that have never been explored before.
APL PhotonicsPhysics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
10.30
自引率
3.60%
发文量
107
审稿时长
19 weeks
期刊介绍:
APL Photonics is the new dedicated home for open access multidisciplinary research from and for the photonics community. The journal publishes fundamental and applied results that significantly advance the knowledge in photonics across physics, chemistry, biology and materials science.