Comparison between personal sampling methodologies for evaluating diesel particulate matter exposures in mines: submicron total carbon corrected for the adsorption of vapor-phase organic carbon vs. respirable total carbon

In the mining industry, personal measurements of elemental and total carbon are frequently used as surrogates of diesel particulate matter (DPM) exposure, and the respirable or submicron fractions are usually measured. However, vapor-phase organic carbon (OC) can be adsorbed in the filters, interfer...

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Bibliographic Details
Published in:Journal of occupational and environmental hygiene 2019-01, Vol.16 (1), p.1-5
Main Authors: Fleck, Alan, Cabelguen, Virginie, Couture, Caroline, Lachapelle, Guillaume, Ryan, Patrick, Thuot, Ross, Debia, Maximilien
Format: Article
Language:English
Subjects:
Adsorption
Aerodynamics
Carbon
Diesel
Exposure
Filters
Gold
Mining
Mining industry
Organic carbon
Particulate matter
Particulates
Samples
Statistical methods
Underground mines
Vapor phases
Vapors
Workers
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Summary:In the mining industry, personal measurements of elemental and total carbon are frequently used as surrogates of diesel particulate matter (DPM) exposure, and the respirable or submicron fractions are usually measured. However, vapor-phase organic carbon (OC) can be adsorbed in the filters, interfering with total carbon results. This study presents a comparative evaluation between the submicron fraction of DPM concentrations corrected for the adsorption of the vapor-phase OC (dynamic blank), and the respirable fraction of DPM corrected for a field blank. Respirable and submicron fractions of total carbon (TC and TC ) and elemental carbon (EC and EC ) concentrations were sampled in parallel, in the workers' breathing zone, in an underground gold mine. A total of 20 full-shift personal samples were taken for each size fraction. Field blanks were collected each day for both the submicron and respirable fractions, while dynamic blank correction was also applied for the submicron fraction. TC presented a larger and statistically different geometric mean concentration compared to TC (98 µg/m vs. 72 µg/m ; p = 0.01), while the concentrations of EC and EC were not statistically different (58 µg/m vs. 54 µg/m ; p = 0.74). Average TC /EC ratio was 1.7, while the TC /EC ratio was 1.3. In addition, 93% of EC had an aerodynamic size lower than 1 µm, while the proportion of TC particles in the submicron fraction was lower (73%). Finally, a similar quantity of OC was found when analyzing the dynamic and field blanks of the filters with the submicron fraction selective size (24 µg and 22 µg, respectively). In conclusion, the correction for the vapor phase OC by the dynamic blank was not a significant correction in our study design compared to the field blank samples. This study suggests that the differences in TC may be explained by the different aerodynamic fractions of DPM collected. In addition, elemental carbon measurements did not seem to be extensively affected by the aerodynamic size of the particles collected.
ISSN:1545-9624
1545-9632
DOI:10.1080/15459624.2018.1532576