Calibration of Quartz-Enhanced Photoacoustic Sensors for Real-Life Adaptation

We report on the use of quartz-enhanced photoacoustic spectroscopy for continuous carbon-dioxide measurements in humid air over a period of six days. The presence of water molecules alters the relaxation rate of the target molecules and thus the amplitude of the photoacoustic signal. Prior to the measurements, the photoacoustic sensor system was pre-calibrated using CO2 mole fractions in the range of 0-10(-3) (0-1000 ppm) and at different relative humidities between 0% and 45%, while assuming a model hypothesis that allowed the photoacoustic signal to be perturbed linearly by H2O content. This calibration technique was compared against an alternative learning-based method, where sensor data from the first two days of the six-day period were used for self-calibration. A commercial non-dispersive infrared sensor was used as a CO2 reference sensor and provided the benchmark for the two calibration procedures. In our case, the self-calibrated method proved to be both more accurate and precise.

Automated summary

This study utilized quartz-enhanced photoacoustic spectroscopy for continuous carbon-dioxide measurements in humid air, revealing that the presence of water molecules can affect the relaxation rate of target molecules and consequently the amplitude of the photoacoustic signal. By pre-calibrating the sensor system and comparing it with a self-calibration method, it was found that the self-calibrated method proved to be more accurate and precise.