Citation:

PANGAEA.939407

Name: Additional measurements of volatile organic compounds by PTR-ToF-MS at Cataract Scout Park, Australia, taken during the COALA-2020 campaign
Published: 2021-12-15
License: https://creativecommons.org/licenses/by/4.0/
Keywords: Australia; Biogenic VOC; biomass burning; PTR-ToF-MS; volatile organic compounds

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Published: 2021-12-15 • DOI registered: 2022-08-12

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Abstract:

Measurements of volatile organic compounds (VOCs) were collected using an Ionicon 4000 Proton Transfer Reaction Time of Flight Mass Spectrometer (PTR-ToF-MS). Measurements were taken at Cataract Scout Park, Appin, N.S.W. (34°14'42.29S 150°49'24.97E) from an inlet 10 m above ground level as part of the Characterizing Organics and Aerosol Loading over Australia (COALA-2020) campaign. The campaign ran from mid-January to mid-March, 2020, with the instrument running from early February. Data presented here corresponds to data used in paper by Mouat et al. (2021a) which spans from 2-6 Feb. 2020. These species are in addition to directly calibrated species archived by Mouat et al. (2021b) in a seperate PANGAEA record. Sample air was drawn down a 20 m PTFE inlet line with a bypass pump (flow rate 1.5 – 3 Lmin-1). Concentrations for compounds presented in this dataset were calculated using methodology proposed in Sekimoto et al. (2017).

Keyword(s):

Australia; Biogenic VOC; biomass burning; PTR-ToF-MS; volatile organic compounds

Related to:

Mouat, Asher P; Kaiser, Jennifer; Paton-Walsh, Clare; Ramirez-Gamboa, Jhonathan; Naylor, Travis A; Simmons, Jack B (2021): Volatile organic compound measurements at Cataract Scout Park, Australia, taken during the COALA-2020 campaign [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.927277

Mouat, Asher P; Paton-Walsh, Clare; Simmons, Jack B; Ramirez-Gamboa, Jhonathan; Griffith, David W T (preprint): Emission factors of long-lived volatile organic compounds from the 2019–2020 Australian wildfires during the COALA campaign. Atmospheric Chemistry and Physics Discussions, https://doi.org/10.5194/acp-2021-742

Mouat, Asher P; Paton-Walsh, Clare; Simmons, Jack B; Ramirez-Gamboa, Jhonathan; Griffith, David W T; Kaiser, Jennifer (2022): Measurement report: Observations of long-lived volatile organic compounds from the 2019–2020 Australian wildfires during the COALA campaign. Atmospheric Chemistry and Physics, 22(17), 11033-11047, https://doi.org/10.5194/acp-22-11033-2022

Sekimoto, Kanako; Li, Shou-Li; Yuan, Bin; Koss, Abigail; Coggon, Matthew; Warneke, Carsten; de Gouw, Joost A (2017): Calculation of the sensitivity of proton-transfer-reaction mass spectrometry (PTR-MS) for organic trace gases using molecular properties. International Journal of Mass Spectrometry, 421, 71-94, https://doi.org/10.1016/j.ijms.2017.04.006

Project(s):

Characterizing Organics and Aerosol Loading over Australia (COALA)

Coverage:

Latitude: -34.245081 * Longitude: 150.823603

Date/Time Start: 2020-03-02T07:00:00 * Date/Time End: 2020-04-02T00:59:00

Event(s):

Cataract_scout_park * Latitude: -34.245081 * Longitude: 150.823603 * Date/Time Start: 2020-01-18T00:00:00 * Date/Time End: 2020-03-19T00:00:00 * Location: Appin, Australia * Campaign: (COALA-2020) * Method/Device: Multiple investigations (MULT)

Comment:

NA = -9999

Parameter(s):

#	Name	Short Name	Unit	Principal Investigator	Method/Device	Comment
1	DATE/TIME	Date/Time		Mouat, Asher P		Geocode
2	Propene	C3H6	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 43.054; Composition: C3H6H+; Compound Name: propene; Limit of Detection (ppt): 182.2799573
3	Formamide	Formamide	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 46.029; Composition: CH3NOH+; Compound Name: formamide; Limit of Detection (ppt): 63.00345068
4	Formic acid	Formic acid	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 47.013; Composition: CH2O2H+; Compound Name: formic acid; Limit of Detection (ppt): 583.9847716
5	1-Butene	1-Butene	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 57.07; Composition: C4H8H+; Compound Name: 1-butene; Limit of Detection (ppt): 132.0774141
6	Acetic acid	Acetic acid	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 61.028; Composition: C2H4O2H+; Compound Name: acetic acid; Limit of Detection (ppt): 127.7404139
7	Nitromethane	Nitromethane	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 62.024; Composition: CH3NO2H+; Compound Name: nitromethane; Limit of Detection (ppt): 18.26636773
8	Furan	Furan	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 69.033; Composition: C4H4OH+; Compound Name: furan; Limit of Detection (ppt): 34.92390402
9	Methylglyoxal	C3H4O2	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 73.028; Composition: C3H4O2H+; Compound Name: methyl glyoxal; Limit of Detection (ppt): 34.06148152
10	Methyl acetate	Methyl acetate	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 75.044; Composition: C3H6O2H+; Compound Name: methyl acetate; Limit of Detection (ppt): 41.56189515
11	2-(3H)Furanone + cis-2-butenediol	2-(3H)furanone + cis-2-butenediol	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 85.028; Composition: C4H4O2H+; Compound Name: 2-(3H)furanone; Limit of Detection (ppt): 22.18258708
12	Cyclopentanone + HCO1	Cyclopentanone + HCO1	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 85.065; Composition: C5H8OH+; Compound Name: cyclopentanone + general HCO1; Limit of Detection (ppt): 10.40952261
13	Methyl propanoate	C4H8O2	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 89.06; Composition: C4H8O2H+; Compound Name: methyl propanoate; Limit of Detection (ppt): 20.66826091
14	Phenol	Phenol	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 95.049; Composition: C6H6OH+; Compound Name: phenol; Limit of Detection (ppt): 13.14971507
15	2-Furfural	2-furfural	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 97.028; Composition: C5H4O2H+; Compound Name: 2-furfural; Limit of Detection (ppt): 13.62479168
16	Hydrocarbons, assorted	HC assorted	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 97.101; Composition: C7H12; Compound Name: Assorted HCs; Limit of Detection (ppt): 21.80535209
17	Maleic anhydride	Maleic anhydride	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 99.06; Composition: C4H2O3; Compound Name: Maleic Anhydride; Limit of Detection (ppt): 14.42708848
18	2-Furanmethanol	2-furanmethanol	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 99.044; Composition: C5H6O2; Compound Name: 2-furanmethanol; Limit of Detection (ppt): 15.88922746
19	Methyl methacrylate	Methyl methacrylate	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 101.06; Composition: C5H8O2H+; Compound Name: methyl methacrylate; Limit of Detection (ppt): 17.82007606
20	Styrene	Styrene	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 105.07; Composition: C8H8H+; Compound Name: styrene; Limit of Detection (ppt): 19.85506197
21	Benzaldehyde	C7H6O	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 107.049; Composition: C7H6OH+; Compound Name: benzaldehyde; Limit of Detection (ppt): 6.238785905
22	5-Methyl furfural + catechol	5-methyl furfural + catechol	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 111.044; Composition: C6H6O2H+; Compound Name: 5-methyl furfural + catechol; Limit of Detection (ppt): 9.450095849
23	C3-Furan	C3-Furan	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 111.08; Composition: C7H10O; Compound Name: C3 Furan; Limit of Detection (ppt): 22.05085994
24	2-Hydroxy-3-methyl-2-cyclopenten-1-one	2-hydroxy-3-methyl-2-cyclopenten-1-one	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 113.06; Composition: C6H8O2H+; Compound Name: 2-hydroxy-3-methyl-2-cyclopenten-1-one; Limit of Detection (ppt): 20.89606223
25	Guaiacol	Guaiacol	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 125.06; Composition: C7H8O2H+; Compound Name: guaiacol; Limit of Detection (ppt): 7.399834905
26	Creosol	C8H10O2	ppbv	Mouat, Asher P	Calculated, according to Sekimoto et al. (2017)	Mass-to-charge: 139.075; Composition: C8H10O2H+; Compound Name: creosol; Limit of Detection (ppt): 7.017019835

License:

Creative Commons Attribution 4.0 International (CC-BY-4.0)

Status:

Curation Level: Enhanced curation (CurationLevelC)

Size:

26975 data points

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Datasets with similar metadata

Mouat, AP; Kaiser, J; Paton-Walsh, C et al. (2021): Volatile organic compound measurements at Cataract Scout Park, Australia, taken during the COALA-2020 campaign. https://doi.org/10.1594/PANGAEA.927277
Griffiths, AD; Williams, AG; Chambers, SD et al. (2021): Radon-222 measurements at Cataract Scout Park, Australia, taken during the COALA-2020 campaign. https://doi.org/10.1594/PANGAEA.928372
Keywood, MD; Humphries, RS; Paton-Walsh, C et al. (2020): Condensation nuclei >3 nm (CN3) measurements at Cataract Scout Park, Australia, taken during the COALA-2020 campaign. https://doi.org/10.1594/PANGAEA.925555