Analytica Chimica Acta

2010

DOI: 10.1016/j.aca.2010.02.006

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Gas collection efficiency of annular denuders: A spreadsheet-based calculator

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,

²

,

Colleen F. Berg

³

et al.

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Introduction2

Measurement Of Trace Hcho Under Elevated O 3 Conditions1

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Comparison Of Ppwd With the Ds-gas Collection Efficiency-1

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Cited by 13 publications

(5 citation statements)

References 26 publications

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“…Low-molecular-weight organic acids have been measured in the gas (Lee et al, 2009;Bao et al, 2012) and particle phases (Boreddy et al, 2017;Miyazaki et al, 2014;van Pinxteren et al, 2014) as well as in precipitation and cloud water (Sun et al, 2016;. Next to known primary anthropogenic (Bock et al, 2017;Kawamura and Kaplan, 1987;Legrand et al, 2007) and biogenic sources (Falkovich et al, 2005;Stavrakou et al, 2012), organic acids are formed as secondary products by atmospheric oxidation processes (Lim et al, 2005;Tilgner and Herrmann, 2010;Hoffmann et al, 2016). However, there are still unknown sources of these short-chained compounds (Millet et al, 2015;Stavrakou et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Development of an online-coupled MARGA upgrade for the 2 h interval quantification of low-molecular-weight organic acids in the gas and particle phases

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,

²

,

³

et al. 2019

Atmos. Meas. Tech.

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Abstract. A method is presented to quantify the low-molecular-weight organic acids such as formic, acetic, propionic, butyric, pyruvic, glycolic, oxalic, malonic, succinic, malic, glutaric, and methanesulfonic acid in the atmospheric gas and particle phases, based on a combination of the Monitor for AeRosols and Gases in ambient Air (MARGA) and an additional ion chromatography (Compact IC) instrument. Therefore, every second hourly integrated MARGA gas and particle samples were collected and analyzed by the Compact IC, resulting in 12 values per day for each phase. A proper separation of the organic target acids was initially tackled by a laboratory IC optimization study, testing different separation columns, eluent compositions and eluent flow rates for both isocratic and gradient elution. Satisfactory resolution of all compounds was achieved using a gradient system with two coupled anion-exchange separation columns. Online pre-concentration with an enrichment factor of approximately 400 was achieved by solid-phase extraction consisting of a methacrylate-polymer-based sorbent with quaternary ammonium groups. The limits of detection of the method range between 0.5 ng m−3 for malonate and 17.4 ng m−3 for glutarate. Precisions are below 1.0 %, except for glycolate (2.9 %) and succinate (1.0 %). Comparisons of inorganic anions measured at the TROPOS research site in Melpitz, Germany, by the original MARGA and the additional Compact IC are in agreement with each other (R2 = 0.95–0.99). Organic acid concentrations from May 2017 as an example period are presented. Monocarboxylic acids were dominant in the gas phase with mean concentrations of 306 ng m−3 for acetic acid, followed by formic (199 ng m−3), propionic (83 ng m−3), pyruvic (76 ng m−3), butyric (34 ng m−3) and glycolic acid (32 ng m−3). Particulate glycolate, oxalate and methanesulfonate were quantified with mean concentrations of 26, 31 and 30 ng m−3, respectively. Elevated concentrations of gas-phase formic acid and particulate oxalate in the late afternoon indicate photochemical formation as a source.

“…Low-molecular-weight organic acids have been measured in the gas (Lee et al, 2009;Bao et al, 2012) and particle phases (Boreddy et al, 2017;Miyazaki et al, 2014;van Pinxteren et al, 2014) as well as in precipitation and cloud water (Sun et al, 2016;. Next to known primary anthropogenic (Bock et al, 2017;Kawamura and Kaplan, 1987;Legrand et al, 2007) and biogenic sources (Falkovich et al, 2005;Stavrakou et al, 2012), organic acids are formed as secondary products by atmospheric oxidation processes (Lim et al, 2005;Tilgner and Herrmann, 2010;Hoffmann et al, 2016). However, there are still unknown sources of these short-chained compounds (Millet et al, 2015;Stavrakou et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Development of an online-coupled MARGA upgrade for the 2 h interval quantification of low-molecular-weight organic acids in the gas and particle phases

¹

,

²

,

³

et al. 2019

Atmos. Meas. Tech.

View full text Add to dashboard Cite

Abstract. A method is presented to quantify the low-molecular-weight organic acids such as formic, acetic, propionic, butyric, pyruvic, glycolic, oxalic, malonic, succinic, malic, glutaric, and methanesulfonic acid in the atmospheric gas and particle phases, based on a combination of the Monitor for AeRosols and Gases in ambient Air (MARGA) and an additional ion chromatography (Compact IC) instrument. Therefore, every second hourly integrated MARGA gas and particle samples were collected and analyzed by the Compact IC, resulting in 12 values per day for each phase. A proper separation of the organic target acids was initially tackled by a laboratory IC optimization study, testing different separation columns, eluent compositions and eluent flow rates for both isocratic and gradient elution. Satisfactory resolution of all compounds was achieved using a gradient system with two coupled anion-exchange separation columns. Online pre-concentration with an enrichment factor of approximately 400 was achieved by solid-phase extraction consisting of a methacrylate-polymer-based sorbent with quaternary ammonium groups. The limits of detection of the method range between 0.5 ng m−3 for malonate and 17.4 ng m−3 for glutarate. Precisions are below 1.0 %, except for glycolate (2.9 %) and succinate (1.0 %). Comparisons of inorganic anions measured at the TROPOS research site in Melpitz, Germany, by the original MARGA and the additional Compact IC are in agreement with each other (R2 = 0.95–0.99). Organic acid concentrations from May 2017 as an example period are presented. Monocarboxylic acids were dominant in the gas phase with mean concentrations of 306 ng m−3 for acetic acid, followed by formic (199 ng m−3), propionic (83 ng m−3), pyruvic (76 ng m−3), butyric (34 ng m−3) and glycolic acid (32 ng m−3). Particulate glycolate, oxalate and methanesulfonate were quantified with mean concentrations of 26, 31 and 30 ng m−3, respectively. Elevated concentrations of gas-phase formic acid and particulate oxalate in the late afternoon indicate photochemical formation as a source.

“…HCHO was not detected by the mGAS when the Nafion wet scrubber was placed before the microchannel scrubber. The removal efficiency of the wet scrubber was estimated to be 99% based on the spreadsheet developed by Berg et al, 45,46 assuming that the Nafion surface acted as a perfect sink for HCHO. The low levels of HCHO and high levels of O 3 could be measured using PD chemistry with treatment of the air sample by two three-way solenoid valves, the active carbon column and the wet scrubber (Fig.…”

Section: Measurement Of Trace Hcho Under Elevated O 3 Conditionsmentioning

confidence: 99%

Mobile monitoring along a street canyon and stationary forest air monitoring of formaldehyde by means of a micro-gas analysis system

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²

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³

et al. 2012

J. Environ. Monit.

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A micro-gas analysis system (μGAS) was developed for mobile monitoring and continuous measurements of atmospheric HCHO. HCHO gas was trapped into an absorbing/reaction solution continuously using a microchannel scrubber in which the microchannels were patterned in a honeycomb structure to form a wide absorbing area with a thin absorbing solution layer. Fluorescence was monitored after reaction of the collected HCHO with 2,4-pentanedione (PD) in the presence of acetic acid/ammonium acetate. The system was portable, battery-driven, highly sensitive (limit of detection = 0.01 ppbv) and had good time resolution (response time 50 s). The results revealed that the PD chemistry was subject to interference from O(3). The mechanism of this interference was investigated and the problem was addressed by incorporating a wet denuder. Mobile monitoring was performed along traffic roads, and elevated HCHO levels in a street canyon were evident upon mapping of the obtained data. The system was also applied to stationary monitoring in a forest in which HCHO formed naturally via reaction of biogenic compounds with oxidants. Concentrations of a few ppbv-HCHO and several-tens of ppbv of O(3) were then simultaneously monitored with the μGAS in forest air monitoring campaigns. The obtained 1 h average data were compared with those obtained by 1 h impinger collection and offsite GC-MS analysis after derivatization with o-(2,3,4,5,6-pentafluorobenzyl)hydroxylamine (PFBOA). From the obtained data in the forest, daily variations of chemical HCHO production and loss are discussed.

“…While these calculations were intended for heat transfer problems, they apply equally well to mass transfer problems. For the uninitiated, however, the use of the original tables from Lundberg et al is difficult; solutions directly relevant to the annular denuder geometry have recently been made available in spreadsheet form [29].…”

Section: … (2)mentioning

confidence: 99%

Miniature open channel scrubbers for gas collection

Toda¹,

Koga²,

et al. 2010

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