An in situ gas chromatograph with automatic detector switching between PTR- and EI-TOF-MS: isomer-resolved measurements of indoor air

Claflin, Megan S.; Pagonis, Demetrios; Finewax, Zachary; Handschy, Anne V.; Day, Douglas A.; Brown, Wyatt L.; Jayne, John T.; Worsnop, Douglas R.; Jimenez, José L.; Ziemann, Paul J.; Gouw, J. A. de; Lerner, B. M.

doi:10.5194/amt-14-133-2021

Cited by 55 publications

(41 citation statements)

References 61 publications

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“…However, the PTR-TOF-MS cannot separate isomers and fragment ions of different origins; thus, the potential indoor formation of formaldehyde and acetaldehyde cannot be evaluated. Real-time separation of isomers requires a PTR-TOF-MS configured with a fast gas chromatograph ( Claflin et al, 2021 ).…”

Section: Resultsmentioning

confidence: 99%

Ethanol-based disinfectant sprays drive rapid changes in the chemical composition of indoor air in residential buildings

Jiang¹,

Ding²,

Isaacson³

et al. 2021

Journal of Hazardous Materials Letters

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Section: Resultsmentioning

confidence: 99%

Ethanol-based disinfectant sprays drive rapid changes in the chemical composition of indoor air in residential buildings

Jiang¹,

Ding²,

Isaacson³

et al. 2021

Journal of Hazardous Materials Letters

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“…As PTR-MS has limited capability to distinguish between isomers, a portion of the VOCs pulled from the cuvettes can be trapped in adsorbent tubes for subsequent GC-MS analysis. Latest developments now allow to operate individual instruments in PTR-ToF-MS or in GC-PTR-ToF-MS (or electron impact-ToF-MS) mode, which makes the separate trapping of VOCs for GC-MS analysis unnecessary (Claflin et al, 2021). The VOC-SCREEN system also correlates VOC emissions with the physiological state of the plant by simultaneous measurements of CO 2 assimilation and transpiration rates.…”

Section: Screening Vocs As Phenotypic Traitsmentioning

confidence: 99%

Trends and applications in plant volatile sampling and analysis

et al. 2021

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Volatile organic compounds (VOCs) released by plants serve as information and defense chemicals in mutualistic and antagonistic interactions and mitigate effects of abiotic stress. Passive and dynamic sampling techniques combined with gas chromatography-mass spectrometry analysis have become routine tools to measure emissions of VOCs and determine their various functions. More recently, knowledge of the roles of plant VOCs in the aboveground environment has led to the exploration of similar functions in the soil and rhizosphere. Moreover, VOC patterns have been recognized as sensitive and time-dependent markers of biotic and abiotic stress. This focused review addresses these developments by presenting recent progress in VOC sampling and analysis. We show advances in the use of small, inexpensive sampling devices and describe methods to monitor plant VOC emissions in the belowground environment. We further address latest trends in real-time measurements of volatilomes in plant phenotyping and most recent developments of small portable devices and VOC sensors for non-invasive VOC fingerprinting of plant disease. These technologies allow for innovative approaches to study plant VOC biology and application in agriculture.

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“…If H 3 O + depletion is negligible, as is the case in this study, the abundance of [M+ H] + ion scales linearly with the concentration of M with a slope equal to the product of the species-dependent reaction rate constant k MH , drift time t, and the H 3 O + reagent ion abundance. The proton-transfer reaction is exothermic, and the ionization-induced fragmentation occurs to varying degrees (∼ 0 % to ∼ 100 %) as the result of dehydration, H 2 elimination, alkyl group loss, or HNO 3 loss (Claflin et al, 2021;Duncianu et al, 2017;Leglise et al, 2019;Pagonis et al, 2019;Yuan et al, 2017), which can be represented by the term F MH + . The observed intensity of any ion is also a function of the ion abundance, I MH + , and ion transmission efficiency, T MH + .…”

Section: Gas-phase Quantificationmentioning

confidence: 99%

“…For instance, a comparison of gas-phase measurements by nitrate ion atmospheric pressure chemical ionization, iodide ion chemical ionization, and the Vocus-PTR shows that they differ in the reported relative abundances of OH-TMB oxidation products (Wang et al, 2020). In addition, artefacts such as ion fragmentation are known to occur for PTR-based techniques (Yuan et al, 2017), which could be substantial (> 70 %) for limonene oxidation products (Claflin et al, 2021;Pagonis et al, 2019); the formation of [M+ H 2 O] + adducts in the EESI-TOF, which has been reported previously to occur to a minor extent (Lopez-Hilfiker et al, 2019), also contributes to the discrepancies between the EESI-TOF and Vocus-PTR. These uncertainties complicate our data interpretation but do not change the overall trend in the sensitivity estimation, as shown below in Fig.…”

Section: Near-molecular Response Factorsmentioning

confidence: 99%

Constraining the response factors of an extractive electrospray ionization mass spectrometer for near-molecular aerosol speciation

et al. 2021

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Abstract. Online characterization of aerosol composition at the near-molecular level is key to understanding chemical reaction mechanisms, kinetics, and sources under various atmospheric conditions. The recently developed extractive electrospray ionization time-of-flight mass spectrometer (EESI-TOF) is capable of detecting a wide range of organic oxidation products in the particle phase in real time with minimal fragmentation. Quantification can sometimes be hindered by a lack of available commercial standards for aerosol constituents, however. Good correlations between the EESI-TOF and other aerosol speciation techniques have been reported, though no attempts have yet been made to parameterize the EESI-TOF response factor for different chemical species. Here, we report the first parameterization of the EESI-TOF response factor for secondary organic aerosol (SOA) at the near-molecular level based on its elemental composition. SOA was formed by ozonolysis of monoterpene or OH oxidation of aromatics inside an oxidation flow reactor (OFR) using ammonium nitrate as seed particles. A Vocus proton-transfer reaction mass spectrometer (Vocus-PTR) and a high-resolution aerosol mass spectrometer (AMS) were used to determine the gas-phase molecular composition and the particle-phase bulk chemical composition, respectively. The EESI response factors towards bulk SOA coating and the inorganic seed particle core were constrained by intercomparison with the AMS. The highest bulk EESI response factor was observed for SOA produced from 1,3,5-trimethylbenzene, followed by those produced from d-limonene and o-cresol, consistent with previous findings. The near-molecular EESI response factors were derived from intercomparisons with Vocus-PTR measurements and were found to vary from 103 to 106 ion counts s−1 ppb−1, mostly within ±1 order of magnitude of their geometric mean of 104.6 ion counts s−1 ppb−1. For aromatic SOA components, the EESI response factors correlated with molecular weight and oxygen content and inversely correlated with volatility. The near-molecular response factors mostly agreed within a factor of 20 for isomers observed across the aromatics and biogenic systems. Parameterization of the near-molecular response factors based on the measured elemental formulae could reproduce the empirically determined response factor for a single volatile organic compound (VOC) system to within a factor of 5 for the configuration of our mass spectrometers. The results demonstrate that standard-free quantification using the EESI-TOF is possible.

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An in situ gas chromatograph with automatic detector switching between PTR- and EI-TOF-MS: isomer-resolved measurements of indoor air

Cited by 55 publications

References 61 publications

Ethanol-based disinfectant sprays drive rapid changes in the chemical composition of indoor air in residential buildings

Ethanol-based disinfectant sprays drive rapid changes in the chemical composition of indoor air in residential buildings

Trends and applications in plant volatile sampling and analysis

Constraining the response factors of an extractive electrospray ionization mass spectrometer for near-molecular aerosol speciation

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