Abstract

Abstract. Elemental carbon (EC) is an important constituent of atmospheric particulate matter because it absorbs solar radiation influencing climate and visibility and it adversely affects human health. The EC measured by thermal methods such as thermal–optical reflectance (TOR) is operationally defined as the carbon that volatilizes from quartz filter samples at elevated temperatures in the presence of oxygen. Here, methods are presented to accurately predict TOR EC using Fourier transform infrared (FT-IR) absorbance spectra from atmospheric particulate matter collected on polytetrafluoroethylene (PTFE or Teflon) filters. This method is similar to the procedure developed for OC in prior work (Dillner and Takahama, 2015). Transmittance FT-IR analysis is rapid, inexpensive and nondestructive to the PTFE filter samples which are routinely collected for mass and elemental analysis in monitoring networks. FT-IR absorbance spectra are obtained from 794 filter samples from seven Interagency Monitoring of PROtected Visual Environment (IMPROVE) sites collected during 2011. Partial least squares regression is used to calibrate sample FT-IR absorbance spectra to collocated TOR EC measurements. The FT-IR spectra are divided into calibration and test sets. Two calibrations are developed: one developed from uniform distribution of samples across the EC mass range (Uniform EC) and one developed from a uniform distribution of Low EC mass samples (EC < 2.4 μg, Low Uniform EC). A hybrid approach which applies the Low EC calibration to Low EC samples and the Uniform EC calibration to all other samples is used to produce predictions for Low EC samples that have mean error on par with parallel TOR EC samples in the same mass range and an estimate of the minimum detection limit (MDL) that is on par with TOR EC MDL. For all samples, this hybrid approach leads to precise and accurate TOR EC predictions by FT-IR as indicated by high coefficient of determination (R2; 0.96), no bias (0.00 μg m−3, a concentration value based on the nominal IMPROVE sample volume of 32.8 m3), low error (0.03 μg m−3) and reasonable normalized error (21 %). These performance metrics can be achieved with various degrees of spectral pretreatment (e.g., including or excluding substrate contributions to the absorbances) and are comparable in precision and accuracy to collocated TOR measurements. Only the normalized error is higher for the FT-IR EC measurements than for collocated TOR. FT-IR spectra are also divided into calibration and test sets by the ratios OC/EC and ammonium/EC to determine the impact of OC and ammonium on EC prediction. We conclude that FT-IR analysis with partial least squares regression is a robust method for accurately predicting TOR EC in IMPROVE network samples, providing complementary information to TOR OC predictions (Dillner and Takahama, 2015) and the organic functional group composition and organic matter estimated previously from the same set of sample spectra (Ruthenburg et al., 2014).

Highlights

  • Elemental carbon (EC) in atmospheric aerosols adversely impacts human health (Janssen et al, 2011) and contributes to climate warming (Bond et al, 2013) and decreased visibility (Hand et al, 2014)

  • The precision between thermal– optical reflectance (TOR) samples is expected to be better than the error between Fourier transform infrared (FT-IR) EC and TOR EC because the TOR samples are collected on the same filter type and analyzed by the same method and as expected the normalized error is lower for the collocated TOR EC

  • A hybrid approach is used for calibration in which samples with Low EC are calibrated with a Low EC calibration and all other samples are calibrated with a calibration that spans the range of EC samples

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Summary

Introduction

Elemental carbon (EC) in atmospheric aerosols adversely impacts human health (Janssen et al, 2011) and contributes to climate warming (Bond et al, 2013) and decreased visibility (Hand et al, 2014). Takahama: Predicting TOR EC measurements from infrared spectra eas of the USA, the Speciation Trends Network/Chemical Speciation Network (Flanagan et al, 2006) in urban areas of the USA, and the European Monitoring and Evaluation Programme (EMEP; Torseth et al, 2012) throughout Europe These regional multi-year data sets are useful for observing trends in particulate concentrations (Hand et al, 2013; Hidy et al, 2014; Torseth et al, 2012) and visibility (Hand et al, 2014), evaluating aerosol transport models (Mao et al, 2011), constraining climate models (Liu et al, 2012) and assessing health impacts (Krall et al, 2013). TOR methods are destructive to the sample and expensive

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