Methane emissions were measured at 6650 sites across six major oil and gas producing regions in Canada to examine regional emission trends, and to derive an inventory estimate for Canada’s upstream oil and gas sector. Emissions varied by fluid type and geographic region, with the heavy oil region of Lloydminster ranking highest on both absolute and intensity-based scales. Emission intensities varied widely for natural gas production, where older, low-producing developments such as Medicine Hat, Alberta showed high emission intensities, and newer developments in Montney, British Columbia showed emission intensities that are amongst the lowest in North America. Overall, we estimate that the Canadian upstream oil and gas methane inventory is underestimated by a factor of 1.5, which is consistent with previous studies of individual regions.
The Corrib GasFieldi nt he SlyneB asinl iesabout 70 kmw est ofC o. Mayo,offshoreI reland.The basinisanarrow Triassic/Jurassic half-grabenandisoneofaseriesofstructurallylinked basins thatarepresent alongthe west coast ofI relanda ndthe BritishI sles. The fieldwasdiscovered in1 996 byw ell 18/20-1, encounteringa61 mgascolumn inlow-porosity Triassic fluvialsandstonesatasubsea depthof3539.6 m. Using extremely poor 2Dseismic data, itw aso riginally mapped asatilted fault block, witha nassociated rollover structureto the east. The dataquality wasp articularly poor dueto the near-surface Palaeogenevolcanicst hat contributeto energydispersion andextrememultiplegeneration.A3Dseismic surveywasacquired in1997 and resulted inamajor improvement indataquality,a llowingi mproved structuralinterpretation thats howed the Corrib Fieldto be afaulted anticline.The subsequent appraisalwell,18/20-2z,drilled approximately 1kmfrom the subsurface location of18/20-1,penetrated a185 mgascolumn infairtogoodquality sandstone.Ittested dry gasatastabilized rateof62.87 £ 10 6 SCF/don a2 00 choke.Reprocessingofthe seismic data, alongwiththe successful drillingofthe followingwell 18/25-1,confirmed the fieldto be arelatively simpleanticlinaltrap,with acomplexfaulted overburdenthatisstructurally detached from the reservoirbythe Mercia Halite.The source rock isassumed to be the WestphalianCoalMeasures,similartothatencountered bywell 27/5-1. The dry gasis consistent withaType-III humic source rock.The reservoirisbiostratigraphically barren,consistingoffluvialred bed sandstone, andi sassumed to be ofT riassic SherwoodS andstoneG roup equivalent age.The unitis approximately 400 mt hick, consistingofahigh net-to-gross sequence oflow-sinuosity braided fluvialchannel sandstoneswithsubordinatesand-flatandplayamudstonedeposits. Onamacro scale, itisaremarkably uniform sandstonewithonly subtlefaciesvariations,but on amicro scalethereisasignificant variation ingrainsizeand cementation,which affects reservoirp roductivity. Mineralogically,therea red istinctdifferencesfrom the SherwoodS andstoneG roup ofthe East IrishS ea, indicatingthatt he SlyneE arly Triassic systemw as depositionallysimilarto,but distinctandseparatefrom,thattothe east ofIreland.Dipmeterdataindicated that the rivers ystemflowed from the SW to NE, essentiallyalongthe direction ofthe present-daySlyneB asin, suggestingthatitwaslargely sourced from the southinthe Variscanhinterland, but withevidence ofsediment input from localhighssuch asthe ConnemaraMassif.
Aggressive reductions of oil and gas sector methane, a potent greenhouse gas, have been proposed in Canada. Few large-scale measurement studies have been conducted to confirm a baseline. This study used a vehicle-based gas monitoring system to measure fugitive and vented gas emissions across Lloydminster (heavy oil), Peace River (heavy oil/bitumen), and Medicine Hat (conventional gas) developments in Alberta, Canada. Four gases (CO2, CH4, H2S, C2H6), and isotopic δ13CCH4 were recorded in real-time at 1 Hz over a six-week field campaign. We sampled 1,299 well pads, containing 2,670 unique wells and facilities, in triplicate. Geochemical emission signatures of fossil fuel-sourced plumes were identified and attributed to nearby, upwind oil and gas well pads, and a point-source gaussian plume dispersion model was used to quantify emissions rates. Our analysis focused exclusively on well pads where emissions were detected >50% of the time when sampled downwind. Emission occurrences and rates were highest in Lloydminster, where 40.8% of sampled well pads were estimated to be emitting methane-rich gas above our minimum detection limits (m = 9.73 m3d–1). Of the well pads we found to be persistently emitting in Lloydminster, an estimated 40.2% (95% CI: 32.2%–49.4%) emitted above the venting threshold in which emissions mitigation under federal regulations would be required. As a result of measured emissions being larger than those reported in government inventories, this study suggests government estimates of infrastructure affected by incoming regulations may be conservative. Comparing emission intensities with available Canadian-based research suggests good general agreement between studies, regardless of the measurement methodology used for detection and quantification. This study also demonstrates the effectiveness in applying a gaussian dispersion model to continuous mobile-sourced emissions data as a first-order leak detection and repair screening methodology for meeting regulatory compliance.
Energy development in southeastern Saskatchewan, Canada, is unique because conventional and unconventional oil and gas production is co-located. Mobile surveys are ideal for understanding emissions in this area because the overlap of production makes it difficult for airborne or satellitebased methods to differentiate emissions from each type of infrastructure. In this study, we conducted truck-based mobile surveys in the unconventional Canadian Bakken and conventional Weyburn-Midale fields to enumerate and attribute individual methane plumes, estimate methane (CH 4 ) emission rates, and compare emission vectors. We sampled downwind of 645 conventional and 289 unconventional sites, covering over 4500 km of public roads. We found that 28% of surveyed conventional sites were emitting, compared to 32% of surveyed unconventional sites. Mean emissions intensities in each development were 20 m 3 CH 4 /day per conventional site and 59 m 3 CH 4 /day per unconventional site. Emissions intensities in southeastern Saskatchewan fall on the lower range of other emissions estimates from developments in the US and Canada.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.