Calibration methodology of low-cost sensors for high-quality monitoring of fine particulate matter.

Low concentrations of pollutants may already be associated with significant health effects. An accurate assessment of individual exposure to pollutants therefore requires measuring pollutant concentrations at the finest possible spatial and temporal scales. Low-cost sensors (LCS) of particulate matter (PM) meet this need so well that their use is constantly growing worldwide. However, everyone agrees that LCS must be calibrated before use. Several calibration studies have already been published, but there is not yet a standardized and well-established methodology for PM sensors. In this work, we develop a method combining an adaptation of an approach developed for gas-phase pollutants with a dust event preprocessing to calibrate PM LCS (PMS7003) commonly used in urban environments. From the selection of outliers to model tuning and error estimation, the developed protocol allows to analyze, process and calibrate LCS data using multilinear (MLR) and random forest (RFR) regressions for comparison with a reference instrument. We demonstrate that the calibration performance was very good for PM and PM but turns out less good for PM (R = 0.94, RMSE = 0.55 μg/m, NRMSE = 12 % for PM with MLR, R = 0.92, RMSE = 0.70 μg/m, NRMSE = 12 % for PM with RFR and R = 0.54, RMSE = 2.98 μg/m, NRMSE = 27 % for PM with RFR). Dust events removal significantly improved LCS accuracy for PM (11 % increase of R and 49 % decrease of RMSE) but no significant changes for PM. Best calibration models included internal relative humidity and temperature for PM and only internal relative humidity for PM. It turns out that PM cannot be properly measured and calibrated because of technical limitations of the PMS7003 sensor. This work therefore provides guidelines for PM LCS calibration. This represents a first step toward standardizing calibration protocols and facilitating collaborative research.