Measurement of the methane isotopologues relaxation rate exploiting quartz-enhanced photoacoustic spectroscopy

“…Due to the high purity of the gas samples, the controlled laboratory environment and the evacuable gas flow system it is not expected that water vapor or other impurities play a major role in the relaxation process. Since there are no significant differences between the relaxation times of the two methane isotopologues, the 13 CH 4 / 12 CH 4 ratio should also not have a substantial influence on the photoacoustic signal (Giglio et al, 2022). As no efficient vibro-vibrational (V-V) transition between the ν 3 state of CH 4 (CH 4 *) and N 2 exists, only three non-radiative relaxation channels are possible (Schilt et al, 2006):…”

“…An alternative to IRMS could be photoacoustic spectroscopy (PAS) (Palzer, 2020). PAS is mainly suitable for the detection of trace gases but has been shown to enable the identification and quantification of methane isotopologues in the single-digit per mill range (Giglio et al, 2022) down to the parts per million (ppm) range (Loh and Wolff, 2019). The latter corresponds to typical concentrations in the atmosphere (van Amstel, 2012).…”

PAS-based isotopologic analysis of highly concentrated methane

“…Due to the high purity of the gas samples, the controlled laboratory environment and the evacuable gas flow system it is not expected that water vapor or other impurities play a major role in the relaxation process. Since there are no significant differences between the relaxation times of the two methane isotopologues, the 13 CH 4 / 12 CH 4 ratio should also not have a substantial influence on the photoacoustic signal (Giglio et al, 2022). As no efficient vibro-vibrational (V-V) transition between the ν 3 state of CH 4 (CH 4 *) and N 2 exists, only three non-radiative relaxation channels are possible (Schilt et al, 2006):…”

“…An alternative to IRMS could be photoacoustic spectroscopy (PAS) (Palzer, 2020). PAS is mainly suitable for the detection of trace gases but has been shown to enable the identification and quantification of methane isotopologues in the single-digit per mill range (Giglio et al, 2022) down to the parts per million (ppm) range (Loh and Wolff, 2019). The latter corresponds to typical concentrations in the atmosphere (van Amstel, 2012).…”

PAS-based isotopologic analysis of highly concentrated methane