Chemical Composition of PM&amp;lt;sub&amp;gt;2.5&amp;lt;/sub&amp;gt; in October 2017 Northern California Wildfire Plumes

Liang, Yutong; Jen, Coty N.; Weber, Robert J.; Misztal, Pawel K.; Goldstein, Allen H.

doi:10.5194/acp-2020-910

Cited by 4 publications

(10 citation statements)

References 79 publications

(105 reference statements)

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“…The test set compounds were quantified using two alternative quantification methods, i.e., manual or closest proxy quantification (described in Liang et al, 2021, which utilizes a combination of both), to benchmark random forest model performance. Manual proxy quantification entails manually assigning a compound to a chemically similar external standard based on researcher judgment on what chemical class the unidentified compound would likely belong to, based on some combination of location in GCxGC space and mass spectrum.…”

Section: Quantification Modeling Performancementioning

confidence: 99%

“…That said, these instrumental configurations are rare, and fragmentation under 14 eV is still sufficiently significant to leave the formulae of many species not identifiable and therefore still uncharacterized (Worton et al, 2017). Recent efforts to embrace a larger fraction of the full complexity of chemical information yielded by highly spe-ciated organic aerosol measurements (on the scale of lowto mid-hundreds of compounds) have categorized unidentified species by likely source groups and chemical families through time series correlations with known tracer species (Zhang et al, 2018) or by manual group assignments by individual researcher judgments based on mass spectral features (Liang et al, 2021). These methods are difficult to standardize and reproduce and become prohibitively inefficient when pushing towards the full chemical complexity of speciated observations produced from typical atmospheric samples, which extend into the low-to mid-thousands of species.…”

Section: Introductionmentioning

confidence: 99%

“…Where possible, compounds in GC and GCxGC-MS are directly quantified by the calibration curves of authentic standards, but direct quantifications are limited by standard expense and availability, even for species that can be positively identified. Compounds that cannot be directly quantified, both in GCxGC-MS and in GC-MS, are most commonly quantified by assigning quantification factors from compounds resolved closely in chromatographic space, compounds that are identified as sharing chemical structures, or some interpolation of multiple nearby proxies (Hatch et al, 2015;Jen et al, 2019;Liang et al, 2021;Zhang et al, 2018). The errors associated with these assignments/choices are usually estimated from the range of quantification factors of close or chemically similar species and are assumed to be high (up to a factor of 2, depending on the degree of certainty in assigning chemical class, as described in Jen et al, 2019 andLiang et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…Compounds that cannot be directly quantified, both in GCxGC-MS and in GC-MS, are most commonly quantified by assigning quantification factors from compounds resolved closely in chromatographic space, compounds that are identified as sharing chemical structures, or some interpolation of multiple nearby proxies (Hatch et al, 2015;Jen et al, 2019;Liang et al, 2021;Zhang et al, 2018). The errors associated with these assignments/choices are usually estimated from the range of quantification factors of close or chemically similar species and are assumed to be high (up to a factor of 2, depending on the degree of certainty in assigning chemical class, as described in Jen et al, 2019 andLiang et al, 2021). To our knowledge, this work presents the first quantitative error analysis of these techniques based on applying proxy quantification techniques to compounds with known quantification factors.…”

Section: Introductionmentioning

confidence: 99%

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Ch3MS-RF: a random forest model for chemical characterization and improved quantification of unidentified atmospheric organics detected by chromatography–mass spectrometry techniques

et al. 2022

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Abstract. The chemical composition of ambient organic aerosols plays a critical role in driving their climate and health-relevant properties and holds important clues to the sources and formation mechanisms of secondary aerosol material. In most ambient atmospheric environments, this composition remains incompletely characterized, with the number of identifiable species consistently outnumbered by those that have no mass spectral matches in the literature or the National Institute of Standards and Technology/National Institutes of Health/Environmental Protection Agency (NIST/NIH/EPA) mass spectral databases, making them nearly impossible to definitively identify. This creates significant challenges in utilizing the full analytical capabilities of techniques which separate and generate spectra for complex environmental samples. In this work, we develop the use of machine learning techniques to quantify and characterize novel, or unidentifiable, organic material. This work introduces Ch3MS-RF (Chemical Characterization by Chromatography–Mass Spectrometry Random Forest Modeling), an open-source, R-based software tool, for efficient machine-learning-enabled characterization of compounds separated in chromatography–mass spectrometry applications but not identifiable by comparison to mass spectral databases. A random forest model is trained and tested on a known 130 component representative external standard to predict the response factors of novel environmental organics based on position in volatility–polarity space and mass spectrum, enabling the reproducible, efficient, and optimized quantification of novel environmental species. Quantification accuracy on a reserved 20 % test set randomly split from the external standard compound list indicates that random forest modeling significantly outperforms the commonly used methods in both precision and accuracy, with a median response factor percent error of −2 %, for modeled response factors, compared to > 15 %, for typically used proxy assignment-based methods. Chemical properties modeling, evaluated on the same reserved 20 % test set and an extrapolation set of species identified in ambient organic aerosol samples collected in the Amazon rainforest, also demonstrate robust performance. Extrapolation set property prediction mean absolute errors for carbon number, oxygen to carbon ratio (O : C), average carbon oxidation state (OSc‾), and vapor pressure are 1.8, 0.15, 0.25, and 1.0 (log(atm)), respectively. Extrapolation set out-of-sample R2 for all properties modeled are above 0.75, with the exception of vapor pressure. While predictive performance for vapor pressure is less robust compared to the other chemical properties modeled, random-forest-based modeling was significantly more accurate than other commonly used methods of vapor pressure prediction, decreasing the mean vapor pressure prediction error to 0.24 (log(atm)) from 0.55 (log(atm)) (chromatography-based vapor pressure prediction) and 1.2 (log(atm)) (chemical formula-based vapor pressure prediction). The random forest model significantly advances an untargeted analysis of the full scope of chemical speciation yielded by two-dimensional gas chromatography (GCxGC-MS) techniques and can be applied to gas chromatography coupled with electron ionization mass spectrometry (GC-MS) as well. It enables the accurate estimation of key chemical properties commonly utilized in the atmospheric chemistry community, which may be used to more efficiently identify important tracers for further individual analysis and to characterize compound populations uniquely formed under specific ambient conditions.

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Section: Quantification Modeling Performancementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Ch3MS-RF: a random forest model for chemical characterization and improved quantification of unidentified atmospheric organics detected by chromatography–mass spectrometry techniques

et al. 2022

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“…The filters were stored at −20 • C prior to analysis. Filters were analyzed using an offline GC × GC coupled to an electron impact/vacuum ultraviolet light ionization source and a high-resolution time-of-flight mass spectrometer (GC × GC EI/VUV HRToFMS), following the same protocols as and Liang et al (2021). Small punches of each filter (with added isotopically labeled internal standards) were thermally desorbed at 320 • C in helium flow using a Gerstel Thermal Desorption System.…”

Section: Filter Analysis By Gc × Gc Ei/vuv Hrtofmsmentioning

confidence: 99%

Emissions of organic compounds from western US wildfires and their near-fire transformations

et al. 2022

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Abstract. The size and frequency of wildfires in the western United States have been increasing, and this trend is projected to continue, with increasing adverse consequences for human health. Gas- and particle-phase organic compounds are the main components of wildfire emissions. Some of the directly emitted compounds are hazardous air pollutants, while others can react with oxidants to form secondary air pollutants such as ozone and secondary organic aerosol (SOA). Further, compounds emitted in the particle phase can volatize during smoke transport and can then serve as precursors for SOA. The extent of pollutant formation from wildfire emissions is dependent in part on the speciation of organic compounds. The most detailed speciation of organic compounds has been achieved in laboratory studies, though recent field campaigns are leading to an increase in such measurements in the field. In this study, we identified and quantified hundreds of gas- and particle-phase organic compounds emitted from conifer-dominated wildfires in the western US, using two two-dimensional gas chromatography coupled with time-of-flight mass spectrometry (GC × GC ToF-MS) instruments. Observed emission factors (EFs) and emission ratios are reported for four wildfires. As has been demonstrated previously, modified combustion efficiency (MCE) was a good predictor of particle-phase EFs (e.g., R2=0.78 and 0.84 for sugars and terpenoids, respectively), except for elemental carbon. Higher emissions of diterpenoids, resin acids, and monoterpenes were observed in the field relative to laboratory studies, likely due to distillation from unburned heated vegetation, which may be underrepresented in laboratory studies. These diterpenoids and resin acids accounted for up to 45 % of total quantified organic aerosol, higher than the contribution from sugar and sugar derivatives. The low volatility of resin acids makes them ideal markers for conifer fire smoke. The speciated measurements also show that evaporation of semi-volatile organic compounds took place in smoke plumes, which suggests that the evaporated primary organic aerosol can be a precursor of SOAs in wildfire smoke plumes.

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Emissions of Organic Compounds from Western US Wildfires and Their Near Fire Transformations

Liang

Stamatis

Fortner

et al. 2022

Preprint

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Abstract. The size and frequency of wildfires in the western United States have been increasing and this trend is projected to continue, with increasing adverse consequences for human health. Gas- and particle-phase organic compounds are the main component of wildfire emissions. Some of the directly emitted compounds are hazardous air pollutants, while others can react with oxidants to form secondary air pollutants such as ozone and secondary organic aerosol (SOA). Further, compounds emitted in the particle phase can volatize during smoke transport and can then serve as precursors for SOA. The extent of pollutant formation from wildfire emissions is dependent in part on the speciation of organic compounds. The most detailed speciation of organic compounds has been achieved in laboratory studies, though recent field campaigns are leading to an increase in such measurements in the field. In this study, we identified and quantified hundreds of gas- and particle-phase organic compounds emitted from conifer-dominated wildfires in the western US, using two two-dimensional gas chromatography coupled with time-of-flight mass spectrometry (GC×GC ToFMS) instruments. Observed emission factors (EFs) and emission ratios are reported for four wildfires. As has been demonstrated previously, modified combustion efficiency (MCE) was a good predictor of particle phase EFs, except for elemental carbon. Higher emissions of diterpenoids, resin acids and monoterpenes were observed in the field relative to laboratory studies; likely due to distillation from unburned heated vegetation, which may be underrepresented in laboratory studies. These diterpenoids and resin acids accounted for up to 45 % of total quantified organic aerosol, higher than the contribution from sugar and sugar derivatives. The low volatility of resin acids makes them ideal markers for conifer fire smoke. The speciated measurements also show that evaporation of semi-volatile organic compounds took place in smoke plumes, which suggests that the evaporated primary organic aerosol can be precursors of SOAs in wildfire smoke plumes.

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Chemical Composition of PM<sub>2.5</sub> in October 2017 Northern California Wildfire Plumes

Cited by 4 publications

References 79 publications

Ch3MS-RF: a random forest model for chemical characterization and improved quantification of unidentified atmospheric organics detected by chromatography–mass spectrometry techniques

Ch3MS-RF: a random forest model for chemical characterization and improved quantification of unidentified atmospheric organics detected by chromatography–mass spectrometry techniques

Emissions of organic compounds from western US wildfires and their near-fire transformations

Emissions of Organic Compounds from Western US Wildfires and Their Near Fire Transformations

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