Airborne Petcoke Dust is a Major Source of Polycyclic Aromatic Hydrocarbons in the Athabasca Oil Sands Region

Zhang, Yifeng; Shotyk, William; Zaccone, Claudio; Noernberg, Tommy; Pelletier, Rick; Bicalho, Beatriz; Froese, Duane G.; Davies, Lauren J.; Martin, Jonathan W.

doi:10.1021/acs.est.5b05092

Cited by 116 publications

(103 citation statements)

References 40 publications

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“…The long-term temporal trends of PAC deposition first shown for lakes relatively close to the more-active surface mining areas (Figure 3) have now been studied among a larger number of lakes, including those farther away such as in the PAD . Results from peat cores (Zhang et al 2016) are also available and largely confirm the temporal and spatial patterns seen from the lake sediments: increases in alk-PAHs, DBTs, and alk-DBTs correspond to the period of OS development and expansion. Harner et al (2018) highlighted results of isotopic analysis (Bosch et al 2015) of sediment cores from a small lake in the PAD (Jautzy et al 2015).…”

Section: Integration Of Air Component Findings-two Examplessupporting

confidence: 57%

“…Consistent with the spatial pattern in air concentrations (Schuster et al 2019), deposition occurs on a gradient, with higher deposition near oil sands production activity. Spatial patterns of PAC deposition have been explored using a variety of methods, including snow (Manzano et al 2016), bulk deposition collectors (Bari, Kindzierski, and Cho 2014), lichen (Graney et al 2017;Landis et al 2019), moss sampling (Zhang et al 2016), and a passive dry deposition sampler (Jariyasopit et al 2018). However, quantitative linkage between concentrations in air and/or precipitation and the levels in these different forms of collection media is difficult to assess (Zhang et al 2016).…”

Section: Integration Of Air Component Findings-two Examplesmentioning

confidence: 99%

“…Petcoke has been of interest given its open storage at the facilities with on-site upgrading and the toxics it contains. Petcoke has been identified in snow (Zhang et al 2016), passive air samplers (Jariyasopit et al 2018), moss (Zhang et al 2016), and lichen (Landis et al 2019). Quantitative estimates of petcoke's and other sources' contributions to PAHs in moss using chemical mass balance (CMB) have been shown to be feasible (Zhang et al 2016).…”

Section: Integration Of Air Component Findings-two Examplesmentioning

confidence: 99%

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Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Brook

Cober

Freemark

et al. 2019

Journal of the Air & Waste Management Association

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The potential environmental impact of air pollutants emitted from the oil sands industry in Alberta, Canada, has received considerable attention. The mining and processing of bitumen to produce synthetic crude oil, and the waste products associated with this activity, lead to significant emissions of gaseous and particle air pollutants. Deposition of pollutants occurs locally (i.e., near the sources) and also potentially at distances downwind, depending upon each pollutant's chemical and physical properties and meteorological conditions. The Joint Oil Sands Monitoring Program (JOSM) was initiated in 2012 by the Government of Canada and the Province of Alberta to enhance or improve monitoring of pollutants and their potential impacts. In support of JOSM, Environment and Climate Change Canada (ECCC) undertook a significant research effort via three components: the Air, Water, and Wildlife components, which were implemented to better estimate baseline conditions related to levels of pollutants in the air and water, amounts of deposition, and exposures experienced by the biota. The criteria air contaminants (e.g., nitrogen oxides [NO x ], sulfur dioxide [SO 2 ], volatile organic compounds [VOCs], particulate matter with an aerodynamic diameter <2.5 μm [PM 2.5 ]) and their secondary atmospheric products were of interest, as well as toxic compounds, particularly polycyclic aromatic compounds (PACs), trace metals, and mercury (Hg). This critical review discusses the challenges of assessing ecosystem impacts and summarizes the major results of these efforts through approximately 2018. Focus is on the emissions to the air and the findings from the Air Component of the ECCC research and linkages to observations of contaminant levels in the surface waters in the region, in aquatic species, as well as in terrestrial and avian species. The existing evidence of impact on these species is briefly discussed, as is the potential for some of them to serve as sentinel species for the ongoing monitoring needed to better understand potential effects, their potential causes, and to detect future changes. Quantification of the atmospheric emissions of multiple pollutants needs to be improved, as does an understanding of the processes influencing fugitive emissions and local and regional deposition patterns. The influence of multiple stressors on biota exposure and response, from natural bitumen and forest fires to climate change, complicates the current ability to attribute effects to air emissions from the industry. However, there is growing evidence of the impact of current levels of PACs on some species, pointing to the need to improve the ability to predict PAC exposures and the key emission source involved. Although this critical review attempts to integrate some of the findings across the components, in terms of ECCC activities, increased coordination or integration of air, water, and wildlife research would enhance deeper scientific understanding. Improved understanding is needed in order to guide the development of longterm mon...

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Section: Integration Of Air Component Findings-two Examplessupporting

confidence: 57%

Section: Integration Of Air Component Findings-two Examplesmentioning

confidence: 99%

Section: Integration Of Air Component Findings-two Examplesmentioning

confidence: 99%

See 1 more Smart Citation

Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Brook

Cober

Freemark

et al. 2019

Journal of the Air & Waste Management Association

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“…This could be due to (1) a lack of emissions estimates from other oil sands sources, such as mine face and facility fugitive emissions (e.g. Zhang et al, 2016), since alkylated PAH and DBT emissions were only estimated from mine fleet, line sources, and tailings ponds; and (2) uncertainties with using monitored concentration ratios (R) between PAHs and alkylated PAHs/DBTs to back-calculate alkylated PAH and DBT emissions (sect. 1.5 in the SI).…”

Section: Total Alkylated Pah and Dbt Concentrationsmentioning

confidence: 99%

“…Model simulations considering only direct air emissions underestimated phenanthrene, pyrene and 5 benzo(a)pyrene concentrations in air, water, soil and foliage, whereas simulations including both direct air emissions and tailings pond emissions were more comparable to observations (Parajulee and Wania, 2014). Another source of airborne PAHs that has not been included in the emissions inventory is petroleum coke stockpiles in the mining areas, which can be resuspended by wind and deposited (Zhang et al, 2016). Analysis of wildlife samples near oil sands development indicate moose and wolves have been exposed to alkylated PAHs from petrogenic sources 10 (Lundin et al, 2015).…”

mentioning

confidence: 99%

Emissions databases for polycyclic aromatic compounds in the Canadian Athabasca Oil Sands Region – development using current knowledge and evaluation with passive sampling and air dispersion modelling data

Qiu¹,

Cheng²,

Yang³

et al. 2017

Preprint

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Abstract. Two speciated and spatially-resolved emissions databases for polycyclic aromatic compounds (PAC) in the Athabasca oil sands region (AOSR) were developed. The first database was derived from volatile organic compound (VOC) emissions data provided by the Cumulative Environmental Management Association (CEMA) and the second database was derived from additional data collected within the Joint Canada-Alberta Oil Sands 15Monitoring (JOSM) program. CALPUFF modelling results for atmospheric polycyclic aromatic hydrocarbons (PAH), alkylated PAH, and dibenzothiophenes (DBT), obtained using each of the emissions databases, are presented and compared with measurements from a passive air monitoring network. The JOSM-derived emissions resulted in better model-measurement agreement in the total PAH concentrations and for most PAH species concentrations, compared to results using CEMA-derived emissions. At local sites near oil sands mines, the percent error of the 20 model compared to observations decreased from 30% using the CEMA-derived emissions to 17% using the JOSMderived emissions. The improvement at local sites was likely attributed to the inclusion of updated tailings pond emissions estimated from JOSM activities. In either the CEMA-derived or JOSM-derived emissions scenario, the model underestimated PAH concentrations by a factor of 3 at remote locations. Potential reasons for the disagreement include forest fire emissions, re-emissions of previously deposited PAHs, and long-range transport not 25 considered in the model. Alkylated PAH and DBT concentrations were also significantly underestimated. The CALPUFF model is expected to predict higher concentrations because of the limited chemistry and deposition modelling. Thus the model underestimation of PACs is likely due to gaps in the emissions database for these compounds and uncertainties in the methodology for estimating the emissions. Future work is required that focuses on improving the PAC emission estimation and speciation methodologies and reducing the uncertainties in VOC 30 emissions which are subsequently used in PAC emissions estimation.Atmos. Chem. Phys. Discuss., https://doi

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Screening of genotoxicity and mutagenicity in extractable organics from oil sands process–affected water

Zetouni

Siraki

Weinfeld

et al. 2016

Enviro Toxic and Chemistry

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Large volumes of oil sands process-affected water (OSPW) are produced by the oil sands surface mining industry during alkaline hot-water extraction of bitumen. It is well documented that the acid extractable organics (AEOs) in OSPW, a highly complex mixture of acidic and polar neutral substances, are acutely toxic; but few studies have examined the genotoxicity or mutagenicity of this mixture. In the present study, the in vitro SOS Chromotest and the Ames test (TA98 and TA100 strains) were used to evaluate genotoxicity and mutagenicity for whole OSPW AEOs in the presence and absence of biotransformation by rat S9 liver enzymes. Two subfractions were also examined in the same assays: neutral extractable fraction (F1-NE), and the subsequent acid extractable fraction (F2-AE). In the SOS assay, whole AEO was cytotoxic when concentrated 2× (i.e., twice as concentrated as the environmental sample) and showed increasing genotoxic response above 6×. Co-exposure with S9 had a protective effect on the cell SOS-inducing factor and survival but did not eliminate genotoxicity above 6× concentrations. Most of the cytotoxicity was attributable to F2-AE, but both F1-NE and F2-AE had similar genotoxic dose-responses above 6×. In the Ames test without S9, whole AEO was mutagenic in both strains above 10× concentrations. Co-incubation with S9 had little effect on the TA100 strain but with TA98 resulted in bioactivation at midlevel doses (1.5-6.3×) and protection at higher doses (10-25×). The 2 subfractions were mutagenic in both strains but with different dose-responses. Further research in vivo or in more relevant cells is warranted to investigate the carcinogenic risks of OSPW. Environ Toxicol Chem 2017;36:1397-1404. © 2016 SETAC.

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Airborne Petcoke Dust is a Major Source of Polycyclic Aromatic Hydrocarbons in the Athabasca Oil Sands Region

Cited by 116 publications

References 40 publications

Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Emissions databases for polycyclic aromatic compounds in the Canadian Athabasca Oil Sands Region – development using current knowledge and evaluation with passive sampling and air dispersion modelling data

Screening of genotoxicity and mutagenicity in extractable organics from oil sands process–affected water

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