# Dual-comb spectroscopy for high-temperature reaction kinetics

**Authors:** Nicolas H. Pinkowski, Yiming Ding, Christopher L. Strand, Ronald K., Hanson, Raphael Horvath, and Markus Geiser

arXiv: 1903.07578 · 2020-04-22

## TL;DR

This study demonstrates the use of a quantum-cascade-laser-based dual-comb spectrometer to analyze high-temperature reaction kinetics of propyne and oxygen in a shock tube, achieving high temporal resolution and accurate measurements.

## Contribution

It introduces a novel application of dual-comb spectroscopy for real-time high-temperature reaction analysis with detailed spectroscopic data.

## Key findings

- Successful measurement of reaction kinetics at 1225 K
- High temporal resolution of 4 microseconds achieved
- Good agreement with independent diagnostics

## Abstract

In the current study, a quantum-cascade-laser-based dual-comb spectrometer (DCS) was used to paint a detailed picture of a 1.0 ms high-temperature reaction between propyne and oxygen. The DCS interfaced with a shock tube to provide pre-ignition conditions of 1225 K, 2.8 atm, and 2% p-C3H4/18% O2/Ar. The spectrometer consisted of two free-running, non-stabilized frequency combs each emitting at 179 wavelengths between 1174 and 1233 cm-1. A free spectral range, f_r, of 9.86 GHz and a difference in comb spacing, {\Delta}f_r, of 5 MHz, enabled a theoretical time resolution of 0.2 us but the data was time-integrated to 4 us to improve SNR. The accuracy of the spectrometer was monitored using a suite of independent laser diagnostics and good agreement observed.

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Source: https://tomesphere.com/paper/1903.07578