Adsorption of water vapour in the solid sorbents used for the sampling of volatile organic compounds

Gawlowski, J.; Gierczak, Tomasz; Jeżo, Agnieszka; Niedzielski, Jan

doi:10.1039/a905039f

Cited by 42 publications

(31 citation statements)

References 11 publications

(13 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…1) and the powdered Parmesan cheese in the analyses performed with a dry purge step. These modifications appeared despite the low water retention on the non-polar porous polymer of the Tenax adsorbent [7,20]. Thus the areas of approximately 40 % of the peaks were strongly modified and 21 out of 79 peaks disappeared from the chromatographic profiles (Tab.…”

Section: Resultsmentioning

confidence: 99%

Analytical artifacts caused by the presence of water vapor in the headspace of food products

Canac-Arteaga¹,

Viallon²,

Berdagué³

2000

Analusis

View full text Add to dashboard Cite

Abstract. Artifacts due to water that appear during analysis by purge-and-trap/GC/MS of naturally moist products were reproduced by increasing the relative humidity of the headspace of measuring cell containing dry and low-moisture products (dehydrated beef stock and powdered Parmesan cheese) by means of a piece of moistened glass wool. The changes observed in the chromatographic profiles of the dry products after humidifying the headspace are explained by interactions between volatile compounds, water and the adsorption trap during the purge-and-trap step.

show abstract

Section: Resultsmentioning

confidence: 99%

Analytical artifacts caused by the presence of water vapor in the headspace of food products

Canac-Arteaga¹,

Viallon²,

Berdagué³

2000

Analusis

View full text Add to dashboard Cite

show abstract

“…In particular, different adsorbents vary greatly in water vapor adsorption capacity (Dettmer and Engewald, 2002;Helmig and Vierling, 1995). Typically, graphitized carbon blacks and Tenax-type of polymeric adsorbents, which retain molecules by pure physical adsorption and do not tend to form hydrogen bonds with water (hydrophobic adsorbents), have low water adsorption capacity, while carbon molecular sieves have high water adsorption capacity (Ciccioli et al, 2002;Engewald, 2002, 2003;Gawlowski et al, 1999;Helmig and Vierling, 1995), likely reflecting the presence of surface oxides in carbon molecular sieves leading to hydrogen bond formation (Dettmer and Engewald, 2002) or due to generation of strong adsorption fields inside the micropores of 5-7Å as the result of overlapping dispersion forces of neighboring pore walls (Ciccioli et al, 2002;Gawlowski et al, 1999). For adsorbents with high water affinity, water vapor can reduce BVOC adsorption efficiency by blocking adsorption sites and thus, reducing the surface area available for BVOC adsorption (Ciccioli et al, 1992;Helmig and Vierling, 1995).…”

Section: Caveats With Sampling On Cartridgesmentioning

confidence: 99%

Estimations of isoprenoid emission capacity from enclosure studies: measurements, data processing, quality and standardized measurement protocols

Niinemets

Kühn²,

Harley³

et al. 2011

Biogeosciences

183

145

View full text Add to dashboard Cite

Abstract. The capacity for volatile isoprenoid production under standardized environmental conditions at a certain time (E S , the emission factor) is a key characteristic in constructing isoprenoid emission inventories. However, there is large variation in published E S estimates for any given species partly driven by dynamic modifications in E S due to acclimation and stress responses. Here we review additional sources of variation in E S estimates that are due to measurement and analytical techniques and calculation and averaging procedures, and demonstrate that estimations of E S critically depend on applied experimental protocols and on data processing and reporting. A great variety of experimental setups has been used in the past, contributing to study-toCorrespondence to:Ü. Niinemets (ylo.niinemets@emu.ee) study variations in E S estimates. We suggest that past experimental data should be distributed into broad quality classes depending on whether the data can or cannot be considered quantitative based on rigorous experimental standards. Apart from analytical issues, the accuracy of E S values is strongly driven by extrapolation and integration errors introduced during data processing. Additional sources of error, especially in meta-database construction, can further arise from inconsistent use of units and expression bases of E S . We propose a standardized experimental protocol for BVOC estimations and highlight basic meta-information that we strongly recommend to report with any E S measurement. We conclude that standardization of experimental and calculation protocols and critical examination of past reports is essential for development of accurate emission factor databases.

show abstract

“…In fact, volatile fatty acids (VFAs) have not been detected with canister sampling and analysis from animal feeding operations (Koziel et al, 2005;Blunden et al, 2005;Filipy et al, 2006) and they are known to be a significant VOC associated with animal production (Zahn et al, 1997;Zahn et al, 2001;Ngwabie et al, 2008). Even alternative air sampling techniques such as sorbent tubes (USEPA Method TO-17) have their own short comings especially when sampling in humid environments using molecular sieve sorbents (Helmig and Vierling, 1995;Gawlowski et al, 1999;Trabue et al, 2008a). Rabaud et al (2002) noted problems with excess water when sampling air from a dairy facility in California.…”

Section: Introductionmentioning

confidence: 99%

Speciation of volatile organic compounds from poultry production

Trabue

Scoggin

et al. 2010

Atmospheric Environment

View full text Add to dashboard Cite

Volatile organic compounds (VOCs) emitted from poultry production are leading source of air quality problems. However, little is known about the speciation and levels of VOCs from poultry production. The objective of this study was the speciation of VOCs from a poultry facility using evacuated canisters and sorbent tubes. Samples were taken during active poultry production cycle and between production cycles. Levels of VOCs were highest in areas with birds and the compounds in those areas had a higher percentage of polar compounds (89%) compared to aliphatic hydrocarbons (2.2%). In areas without birds, levels of VOCs were 1/3 those with birds present and compounds had a higher total percentage of aliphatic hydrocarbons (25%). Of the VOCs quantified in this study, no single sampling method was capable of quantifying more than 55% of compounds and in several sections of the building each sampling method quantified less than 50% of the quantifiable VOCs. Key classes of chemicals quantified using evacuated canisters included both alcohols and ketones, while sorbent tube samples included volatile fatty acids and ketones. Volatile organic compounds (VOCs) emitted from poultry production are leading source of air quality problems. However, little is known about the speciation and levels of VOCs from poultry production. The objective of this study was the speciation of VOCs from a poultry facility using evacuated canisters and sorbent tubes. Samples were taken during active poultry production cycle and between production cycles. Levels of VOCs were highest in areas with birds and the compounds in those areas had a higher percentage of polar compounds (89%) compared to aliphatic hydrocarbons (2.2%). In areas without birds, levels of VOCs were 1/3 those with birds present and compounds had a higher total percentage of aliphatic hydrocarbons (25%). Of the VOCs quantified in this study, no single sampling method was capable of quantifying more than 55% of compounds and in several sections of the building each sampling method quantified less than 50% of the quantifiable VOCs. Key classes of chemicals quantified using evacuated canisters included both alcohols and ketones, while sorbent tube samples included volatile fatty acids and ketones. The top five compounds made up close to 70% of VOCs and included: 1) acetic acid (830.1 mg m À3 ); 2) 2,3-butanedione (680.6 mg m À3 ); 3) methanol (195.8 mg m À3 ); 4) acetone (104.6 mg m À3 ); and 5) ethanol (101.9 mg m À3 ). Location variations for top five compounds averaged 49.5% in each section of the building and averaged 87% for the entire building.Published by Elsevier Ltd.

show abstract

Adsorption of water vapour in the solid sorbents used for the sampling of volatile organic compounds

Cited by 42 publications

References 11 publications

Analytical artifacts caused by the presence of water vapor in the headspace of food products

Analytical artifacts caused by the presence of water vapor in the headspace of food products

Estimations of isoprenoid emission capacity from enclosure studies: measurements, data processing, quality and standardized measurement protocols

Speciation of volatile organic compounds from poultry production

Contact Info

Product

Resources

About