Mid-infrared dual-comb spectroscopy with quantum cascade lasers

Hayden, Jakob; Geiser, Markus; Gianella, Michele; Horvath, Raphael; Hugi, Andreas; Sterczewski, Lukasz; Mangold, Markus

doi:10.1063/5.0159042

Cited by 4 publications

(1 citation statement)

References 163 publications

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“…Here, we apply quantum cascade laser dual-comb spectroscopy (QCL-DCS) 23 , 24 at a wavelength near = 9.4 μm to study NH 3 formation in a low-pressure, nitrogen-hydrogen (N 2 –H 2 ) plasma. This study highlights several advantages of QCL-DCS as a diagnostic tool for probing complex environments like a non-thermal plasma, including high spectral resolution (4.5 × 10 −4 cm −1 or 14 MHz) and broad spectral coverage (50 cm −1 ).…”

Section: Introductionmentioning

confidence: 99%

Dual-comb spectroscopy of ammonia formation in non-thermal plasmas

Sadiek,

Fleisher,

Hayden

et al. 2024

Commun Chem

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Plasma-activated chemical transformations promise the efficient synthesis of salient chemical products. However, the reaction pathways that lead to desirable products are often unknown, and key quantum-state-resolved information regarding the involved molecular species is lacking. Here we use quantum cascade laser dual-comb spectroscopy (QCL-DCS) to probe plasma-activated NH3 generation with rotational and vibrational state resolution, quantifying state-specific number densities via broadband spectral analysis. The measurements reveal unique translational, rotational and vibrational temperatures for NH3 products, indicative of a highly reactive, non-thermal environment. Ultimately, we postulate on the energy transfer mechanisms that explain trends in temperatures and number densities observed for NH3 generated in low-pressure nitrogen-hydrogen (N2–H2) plasmas.

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Section: Introductionmentioning

confidence: 99%

Dual-comb spectroscopy of ammonia formation in non-thermal plasmas

Sadiek,

Fleisher,

Hayden

et al. 2024

Commun Chem

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Optical frequency combs: Driving precision across the fundamental and applied research domains

Fortier,

Torres-Company

2024

APL Photonics

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Monolithic dispersion engineered mid-infrared quantum cascade laser frequency comb

Wu,

Ma,

Sun

et al. 2024

Photon. Res.

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The high-power quantum cascade laser (QCL) frequency comb capable of room temperature operation is of great interest to high-precision measurement and low-noise molecular spectroscopy. While a significant amount of research is devoted to the longwave spectral range, shortwave 3–5 μm QCL combs are still relatively underdeveloped due to the excessive material dispersion. In this work, we propose a monolithic integrated multimode waveguide scheme for effective dispersion engineering and high-power-efficiency operation. Over watt-level output power at room temperature with a wall plug efficiency of 7% and robust dispersion reduction is achieved from a quantum cascade laser frequency comb at a wavelength approximately 4.6 μm. Narrow beatnote linewidth less than 1 kHz and clear dual-comb multiheterodyne comb lines manifest the coherent phase relation among the comb modes which is crucial to fast molecular spectroscopy. This monolithic dispersion engineered waveguide design is also compatible to an efficient active–passive optical coupling scheme and would open up a new research playground for ring comb and on-chip dual-comb spectroscopy.

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Mid-infrared dual-comb spectroscopy with quantum cascade lasers

Cited by 4 publications

References 163 publications

Dual-comb spectroscopy of ammonia formation in non-thermal plasmas

Dual-comb spectroscopy of ammonia formation in non-thermal plasmas

Optical frequency combs: Driving precision across the fundamental and applied research domains

Monolithic dispersion engineered mid-infrared quantum cascade laser frequency comb

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