Technical Note: Development of chemoinformatic tools to enumerate functional groups in molecules for organic aerosol characterization

Ruggeri, Giulia; Takahama, Satoshi

doi:10.5194/acp-16-4401-2016

Cited by 25 publications

(61 citation statements)

References 91 publications

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“…Only relative metrics are used as Sax et al (2005) reported measurements in mole fractions of FGs, and the simulations do not include wall losses of particles and SVOCs that affect overall estimates of yield. Neglecting compound-specific SVOC deposition to walls may further incur biases in relative compositions as raised by Ruggeri et al (2016), but for this conceptual study we neglect its effect as its parameters are not precisely known.…”

Section: Data Setmentioning

confidence: 99%

“…Furthermore, this approach allows development of parameterizations to more precisely estimate the organic carbon content from measured FG abundance. We use simulated photooxidation products of α-pinene secondary organic aerosol previously reported by Ruggeri et al (2016) and FG measurements by Fourier transform infrared (FT-IR) spectroscopy in chamber experiments by Sax et al (2005) to infer the relationships among molecular composition, FG composition, and metrics of organic aerosol functionalization. We find that for this simulated system, ∼ 80 % of the carbon atoms should be detected by FGs for which calibration models are commonly developed, and ∼ 7 % of the carbon atoms are undetectable by FT-IR analysis because they are not associated with vibrational modes in the infrared.…”

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confidence: 99%

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Takahama¹

2017

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Functional group (FG) analysis provides a means by which functionalization in organic aerosol can be attributed to the abundances of its underlying molecular structures. However, performing this attribution requires additional, unobserved details about the molecular mixture to provide constraints in the estimation process. We present an approach for conceptualizing FG measurements of organic aerosol in terms of its functionalized carbon atoms. This reformulation facilitates estimation of mass recovery and biases in popular carbon-centric metrics that describe the extent of functionalization (such as oxygen to carbon ratio, organic mass to organic carbon mass ratio, and mean carbon oxidation state) for any given set of molecules and FGs analyzed. Furthermore, this approach allows development of parameterizations to more precisely estimate the organic carbon content from measured FG abundance. We use simulated photooxidation products of α-pinene secondary organic aerosol previously reported by Ruggeri et al. (2016) and FG measurements by Fourier transform infrared (FT-IR) spectroscopy in chamber experiments by Sax et al. (2005) to infer the relationships among molecular composition, FG composition, and metrics of organic aerosol functionalization. We find that for this simulated system, ∼ 80 % of the carbon atoms should be detected by FGs for which calibration models are commonly developed, and ∼ 7 % of the carbon atoms are undetectable by FT-IR analysis because they are not associated with vibrational modes in the infrared. Estimated biases due to undetected carbon fraction for these simulations are used to make adjustments in these carbon-centric metrics such that model-measurement differences are framed in terms of unmeasured heteroatoms (e.g., in hydroperoxide and nitrate groups for the case studied in this demonstration). The formality of this method provides framework for extending FG analysis to not only model-measurement but also instrument intercomparisons in other chemical systems.Published by Copernicus Publications on behalf of the European Geosciences Union.

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Section: Data Setmentioning

confidence: 99%

mentioning

confidence: 99%

Response to Reviewer 1

Takahama¹

2017

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“…1710 -1680 Aromatic polycarboxylic acids (C=O) [12] 1706 C=O in aldehydes and ketones [55] 1700 Carbonyl (C=O) [54] 1690 -1680 Hydrogen bonded (O-H) [8] 1680 -1665, 1660 -1630 Aliphatic hydrocarbons (C=C) [12] 1680 -1630 C=O stretch in amide [44] 1680 -1620 Unsaturated aliphatic (C=C) [48] 1650 -1620 Alkenyl double bond stretch (C=C) [10] 1650 -1590 Amino (C-NH 2 ) [48] 1644, 1281, 849 O-N groups [31] 1640 -1560 N-H bend in primary amines [44] 1640 -1550 Primary and secondary amide N-H bend [44] 1440 -1220 Alcohol and phenol (C-O-H bend) [44] 1400 -1390 C-H deformation of CH 3 groups [52] 1400 OH in carbohydrates [12] 1400 C-H in carbohydrates [12] 1350 -1340 Nitro-aromatic (NO 2 ) [42] 1350 -1000 C-N stretch in amines [44] 1340 -1250 Aromatic (C-N) [48] 1320 -1210 Aliphatic carboxylic acids (CO) [12] 1320 -1210 Amino acids/Amines (CO) [12] 1300 -1100 Ketone C (C=O)C bend [44] 1300-1000 C-O stretch in ether, ester [44] 1298 -1200 Organonitrates [46] 1286, 1249, 1222 -CH 2 wagging [50] 1280 Organonitrate [41] 1280 -1278, 1631 Organonitrate [53] 1280 -1270 Organonitrate (ONO 2 ) [42] 1280 -1210 Esters/ethers/phenols (C-O) [7] 1280 -1137 C-O stretching of esters, ethers and phenols [52] 1280 Symmetric NO 2 stretch in organonitrate [44] G. 1260 -700 Alkane skeletal vibration (C-C) [38] 1220 C-O stretching and O-H bending vibrations of COOH [5] 1210 -1160, 1100 -1030 Esters/Lactones (C-C-O) [12] 1200 -900 Carbohydrates (C-O-C) [12] 1182 C-O-C stretching …”

Section: Ftir Spectral Interpretations For Characteristic Groups In Omentioning

confidence: 99%

“…A comprehensive interpretation of FTIR spectra has been tabulated in Aliphatic carboxylic acids (OH) and Amino acids/Amines (OH) [12] 3500 -2500 Carbohydrates (C-OH) [12] 3500 -3100 Organic hydroxyl (C-OH) [19] 3440 -3400 Hydroxyl (-OH) [30] 3400 -2500 Carboxylic acid (OH) [45] 3400-2400 Carboxylic acid (OH stretch) [24] [ 44] 3400, 1440 -1220, 1260 -1000 Alcohol and phenol [44] 3400, 1625 Amine (NH 2 ) [19] [20] 3400 OH stretching of phenol hydroxyl and carboxyl [5] 3382 -3323 Alcohol (OH) [45] 3380 H-bonding of hydroxyl [46] 3350, 1350, 650 ± 50 Alcohols/Phenols (OH) [12] 3350 -3205 Alcohol COH [24] 3350, 3180 Primary amide N-H stretch [44] 3300 -3150 Alcohol groups [33] 3300 -2900 C-H stretching in alkane, alkene, alkyne, aromatic [44] 3300 Secondary amide N-H stretch [44] 3300 Hydrogen bonded [8] 3200 -3000, 1290 -1000 Aromatic carbon (Arom-H) [38] G. 3200 -3000 Aromatic carbons (Arom-H) [36] 3130 -3030, 900 -670 Aromatic (C=C-H) [48] 3100 -3070 Carboxylic acid (COOH) [30] 3100 -3000 Aromatic (C-H) [42] 3100 -2900 Unsaturated aliphatic (C=C-H) [17] [19] [20] 3100 -3000 Alkene (C-H) [38] 3100 -3000 Aromatic (C=C-H) [17] [19] [20] 3100 -3000 Unsaturated aliphatic (C=C-H) [48] 3100 -3000 Unsaturated and aromatic (C-H) [12] 3100 H-bonding of organic acid [46] 3100 -2900 Alkane groups [33] 3090 -3075, 3050 -3000, 990 -815 Aliphatic Hydrocarbons (C-H) [12] 3050 Aromatic (C-H) [24] [ …”

Section: Ftir Spectral Interpretations For Characteristic Groups In Omentioning

confidence: 99%

Applications of Infrared Spectroscopy in Analysis of Organic Aerosols

Cao¹,

Yan²,

Zou³

et al. 2018

SAR

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This paper reviews the studies of using FTIR to investigate the components of aerosols produced in smog chamber experiments and collected in atmosphere. The fact that aerosols are mixture of small amount of countless individual compounds makes the analysis of aerosol constituents very challenging. Although a number of advanced instruments have been applied to the chemical characterization of aerosol components, the majority of aerosol components, particularly the organics, remain unknown. Being supplemental to the traditional quantitative instruments, FTIR has been recently used either individually or combining with other analytical instruments to characterize the components of aerosol particles. This paper aims to show how FTIR is applied to analysis of organic aerosols in current literature and to summarize the FTIR characteristic peak frequencies that are widely seen in the FTIR measurement of organic aerosols. It will be greatly helpful to researchers whose studies are focused on the analysis of aerosol components.

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“…When particulate matter samples are analyzed directly, the totality of OA can be characterized. OA is described by FT-IR analysis as the sum of organic functional groups, i.e., alkyl (C-H) bonds, carbonyl (C=O), carboxyl (C(OH)=O), amine (NH), hydroxyl (C-OH) groups, organic sulfate, and organic nitrate (Russell et al, 2011;Ruggeri and Takahama, 2016). Time resolution is limited by the detection limit and ambient OA concentrations.…”

mentioning

confidence: 99%

Advances in Organic Aerosol Characterization: From Complex to Simple

Gilardoni

2017

Aerosol Air Qual. Res.

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Technical Note: Development of chemoinformatic tools to enumerate functional groups in molecules for organic aerosol characterization

Cited by 25 publications

References 91 publications

Response to Reviewer 1

Response to Reviewer 1

Applications of Infrared Spectroscopy in Analysis of Organic Aerosols

Advances in Organic Aerosol Characterization: From Complex to Simple

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