The Quest CCS Project: 1st Year Review Post Start of Injection

Rock, Luc; O’Brien, Simon; Tessarolo, Stephen; Duer, Jeff; Bacci, Vicente Oropeza; Hirst, Bill; Randell, David; Helmy, Mohamed; Blackmore, Jessica; Duong, Celina; Halladay, Anne; Smith, Nial; Dixit, Tanu; Kassam, Sarah; Yaychuk, Matthew

doi:10.1016/j.egypro.2017.03.1654

Cited by 56 publications

(23 citation statements)

References 2 publications

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“…Among large-scale CCS facilities in the world with a capacity of at least 400,000 t/y, nineteen of them were operating in 2019 [26]. In Table 2, information on the CCS projects based on the Global CCS Institute (GCCSI) database [27] and additional surveys [28][29][30][31][32][33][34][35][36] is listed.…”

Section: Co 2 Capture In Large-scale Ccs Facilitiesmentioning

confidence: 99%

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Amine-based capture of CO2 for utilization and storage

Yamada

2020

Polym J

118

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Carbon dioxide capture and storage (CCS) technology is an effective CO 2 fixation technology, as documented by the special report produced by Working Group III of the Intergovernmental Panel on Climate Change. Today, this technology has become important due to the threat of global warming and climate change. Furthermore, the development of carbon dioxide capture and utilization (CCU) technology, which reuses the captured CO 2 , has been prioritized in recent years to accelerate the deployment of "CCUS." For both utilization and storage, CO 2 capture is a key process that determines how efficiently decarbonation is able to meet the global target. Regardless of the maturity of various types of CO 2 capture technologies, amines are the most widely used chemical species. This paper contains a brief overview of CCUS followed by a discussion of several aspects of amine-based CO 2 capture technologies.

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Section: Co 2 Capture In Large-scale Ccs Facilitiesmentioning

confidence: 99%

“…Based on the GCCSI database[26,27] and additional surveys[28][29][30][31][32][33][34][35][36]. NG natural gas processing, C 4 H 6 O 3 propylene carbonate Breakdown of CO 2 capture amounts in the nineteen large-scale CCS facilities in operation reaction and (ii) regeneration of the material used for CO 2 separation by a reverse reaction.…”

mentioning

confidence: 99%

Amine-based capture of CO2 for utilization and storage

Yamada

2020

Polym J

118

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“…Processes would have to be inexpensive to engineer and politically acceptable to society. Power generation linked to classical carbon capture and storage (CCS) approaches, that simply cycle carbon bearing species (oil or gas or coal), through the power generator at the surface and return waste CO2 to the subsurface, are technically mature and are being demonstrated in commercial pilots worldwide (Rock et al, 2017) , though there are political and economic challenges to overcome. It is estimated that perhaps 12% of our CO2 emissions could be stored in this way (Rogelj et al, 2018) .…”

Section: Potential Zero Emission Energy Routes From Fossil Fuelsmentioning

confidence: 99%

“…A) Conventional fossil fuel production combined directly with power generation and Carbon Capture and Storage. These are established approaches being technically demonstrated at scale currently (Rock et al, 2017) and are not further discussed here.…”

Section: Potential Zero Emission Energy Routes From Fossil Fuelsmentioning

confidence: 99%

Can fossil fuel energy be recovered and used without any CO2 emissions to the atmosphere?

Novotnik

Nandy

Venkatesan

et al. 2020

Rev Environ Sci Biotechnol

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The world's energy system is still dominated by fossil fuels. While there is a rapid reduction in the cost of renewable energy and the environmental costs of continued carbon dioxide emissions from fossil fuel recovery and use are well understood, current economic, infrastructure and political constraints sustain the fossil fuel enterprise as a dominant component of the energy system. Though routes to decarbonizing fossil fuel use, such as carbon capture and storage, have been proposed and have been demonstrated at commercial scale, current CCS CO2 storage quantities are very small and no large-scale practical route to providing fossil fuel energy, without the CO2 emissions attendant with fuel production and use has been proposed. Here we look at some of the boundary conditions and possible routes to production of emissions free energy from fossil fuels, and specifically petroleum reservoirs. Focusing on the production of electrical power we look at possible applications of microbially mediated hydrocarbon oxidation, coupled to a range of energy harvesting strategies, to the provision of electrical power at surface at a range of scales suitable for grid power provision, powering upstream oilfield facilities or for powering in situ sensing and exploration systems. We also ask the question, even if practical, would direct production of electrical power from oil and gas fields be a politically and economically sensible strategy as part of the energy transition away from traditional fossil fuel use.

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“…Existing CO 2 storage technologies are sufficient to support mega-tonne/year CO 2 storage projects where there is the freedom to avoid the identified risks to secure long-term storage through careful site selection. Commercial-scale demonstration projects such as the Quest project in Alberta, Canada (Luc Rock, 2016), or the Illinois Basin-Decatur project in Illinois, USA (Traci Rodosta, 2017), have shown that the technology at this scale is feasible and safe. However, scaling CO 2 storage capabilities to deliver giga-tonne/year storage remains a CCS industry challenge.…”

Section: Scale-up Challengementioning

confidence: 99%

Scaling Technologies To Enable Giga-Tonne/Year CO2 Storage

Dean¹,

Bourne²,

Смит³

et al. 2018

Proceedings

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Carbon Capture and Storage (CCS) is a key climate mitigation technology required to meet the Paris Agreement goal of limiting global warming. Commercial-scale demonstration projects such as the Quest project in Alberta, Canada, or the Illinois Basin-Decatur project in Illinois, USA, have shown that the technology is feasible and safe. These projects demonstrate that existing technologies are sufficient for the successful implementation of CCS at the mega-tonne/year scale. However, scaling these technologies to meet the future need for giga-tonne/year storage remains a shared industry challenge. Responding to it demands addressing the low-probability, highimpact storage risks that cannot always be avoided within a large and diverse portfolio of CO2 storage projects. These include the risk of induced seismicity and fault reactivation, pressure management to improve storage security, exposure to legacy wells, and lowering the cost of large-scale containment monitoring. We propose four technology development pathways to address these giga-ton/year challenges, highlighting key focus areas.

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The Quest CCS Project: 1st Year Review Post Start of Injection

Cited by 56 publications

References 2 publications

Amine-based capture of CO2 for utilization and storage

Amine-based capture of CO2 for utilization and storage

Can fossil fuel energy be recovered and used without any CO2 emissions to the atmosphere?

Scaling Technologies To Enable Giga-Tonne/Year CO2 Storage

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