Long-term calibration models to estimate ozone concentrations with a metal oxide sensor

Tofigh Sayahi; Alicia Garff; Timothy Quah; Katrina Lê; Thomas Becnel; Kody M Powell; Pierre-Emmanuel Gaillardon; Anthony E Butterfield; Kerry E Kelly

doi:10.1016/j.envpol.2020.115363

Long-term calibration models to estimate ozone concentrations with a metal oxide sensor

Environ Pollut. 2020 Dec:267:115363. doi: 10.1016/j.envpol.2020.115363. Epub 2020 Aug 12.

Authors

Tofigh Sayahi¹, Alicia Garff², Timothy Quah³, Katrina Lê⁴, Thomas Becnel⁵, Kody M Powell⁴, Pierre-Emmanuel Gaillardon⁵, Anthony E Butterfield⁴, Kerry E Kelly⁴

Affiliations

¹ University of Utah, Department of Chemical Engineering, 3290 MEB, 50 S. Central Campus Dr., Salt Lake City, UT, United States. Electronic address: tofighsayahi@chemeng.utah.edu.
² University of Utah, Department of Physics and Astronomy, 201 James Fletcher Building, 115 S. 1400 E, Salt Lake City, UT, United States.
³ University of California, Santa Barbara, Department of Chemical Engineering, 3357 Engrg II, Santa Barbara, CA, United States.
⁴ University of Utah, Department of Chemical Engineering, 3290 MEB, 50 S. Central Campus Dr., Salt Lake City, UT, United States.
⁵ University of Utah, Department of Electrical and Computer Engineering, Laboratory for NanoIntegrated Systems, 50 S. Central Campus Dr., Salt Lake City, UT, United States.

PMID: 32871483
DOI: 10.1016/j.envpol.2020.115363

Abstract

Ozone (O₃) is a potent oxidant associated with adverse health effects. Low-cost O₃ sensors, such as metal oxide (MO) sensors, can complement regulatory O₃ measurements and enhance the spatiotemporal resolution of measurements. However, the quality of MO sensor data remains a challenge. The University of Utah has a network of low-cost air quality sensors (called AirU) that primarily measures PM_2.5 concentrations around the Salt Lake City valley (Utah, U.S.). The AirU package also contains a low-cost MO sensor ($8) that measures oxidizing/reducing species. These MO sensors exhibited excellent laboratory response to O₃ although they exhibited some intra-sensor variability. Field performance was evaluated by placing eight AirUs at two Division of Air Quality (DAQ) monitoring stations with O₃ federal equivalence methods for one year to develop long-term multiple linear regression (MLR) and artificial neural network (ANN) calibration models to predict O₃ concentrations. Six sensors served as train/test sets. The remaining two sensors served as a holdout set to evaluate the applicability of the new calibration models in predicting O₃ concentrations for other sensors of the same type. A rigorous variable selection method was also performed by least absolute shrinkage and selection operator (LASSO), MLR and ANN models. The variable selection indicated that the AirU's MO oxidizing species and temperature measurements and DAQ's solar radiation measurements were the most important variables. The MLR calibration model exhibited moderate performance (R² = 0.491), and the ANN exhibited good performance (R² = 0.767) for the holdout set. We also evaluated the performance of the MLR and ANN models in predicting O₃ for five months after the calibration period and the results showed moderate correlations (R²s of 0.427 and 0.567, respectively). These low-cost MO sensors combined with a long-term ANN calibration model can complement reference measurements to understand geospatial and temporal differences in O₃ levels.

Keywords: Long-term calibration; Low-cost sensors; Metal oxide; Ozone.

MeSH terms

Air Pollutants* / analysis
Calibration
Cities
Environmental Monitoring
Metals
Oxides
Ozone* / analysis
Utah

Substances

Air Pollutants
Metals
Oxides
Ozone