Direct Comb Vernier Spectroscopy for Fractional Isotopic Ratio Determinations

Accurate isotopic composition analysis of the greenhouse-gasses emitted in the atmosphere is an important step to mitigate global climate warnings. Optical frequency comb-based spectroscopic techniques have shown ideal performance to accomplish the simultaneous monitoring of the different isotope substituted species of such gases. The capabilities of one such technique, namely, direct comb Vernier spectroscopy, to determine the fractional isotopic ratio composition are discussed. This technique combines interferometric filtering of the comb source in a Fabry-Perot that contains the sample gas, with a high resolution dispersion spectrometer to resolve the spectral content of each interacting frequency inside of the Fabry-Perot. Following this methodology, simultaneous spectra of ro-vibrational transitions of (CO2)-C-12-O-16 and (CO2)-C-13-O-16 molecules are recorded and analyzed with an accurate fitting procedure. Fractional isotopic ratio C-13/C-12 at 3% of precision is measured for a sample of CO2 gas, showing the potentialities of the technique for all isotopic-related applications of this important pollutant.

Automated summary

Accurate isotopic composition analysis of greenhouse gases in the atmosphere is crucial for mitigating global climate change. Optical frequency comb-based spectroscopic techniques, such as direct comb Vernier spectroscopy, have shown promising capabilities for simultaneously monitoring different isotopic species of these gases. By combining interferometric filtering with a high-resolution dispersion spectrometer, this technique can accurately measure the fractional isotopic ratio composition, as demonstrated in this study.