Litcius/Paper detail

Application and Research Progress of CO<sub>2</sub> Stimulation Technology in Unconventional Oil and Gas Reservoirs: A Review and Prospect

Lipei Fu, Yefeng Shao, Minglu Shao, Tongyu Zhu, Xiaoxiao Li, Zhiguo Yang, Jirui Zou, Mingfu Fan, Kaili Liao

2023Energy & Fuels15 citationsDOI

Abstract

Efficient exploitation of unconventional oil and gas resources plays an indelible role in meeting national development requirements and daily consumption and ensuring national resource security, but it is difficult to achieve efficient exploitation by traditional fracturing and oil displacement methods. Carbon dioxide (CO 2 ) fracturing technology and flooding technology have become important means to enhance oil recovery of unconventional oil and gas reservoirs because of advantages of the significant effect on the production increase, small damage to the reservoir, large scope of application, and low cost. In this paper, the mechanism and technology of CO 2 in fracturing, flooding, and storage are analyzed on the basis of the current research status of CO 2 in the field of unconventional oil and gas production. The application examples and related research of CO 2 fracturing technology, flooding technology, and storage technology used in oil and gas reservoirs both domestically and internationally are reviewed. The related application technologies and technical bottlenecks are discussed. Eventually, the related technologies of CO 2 are prospected. It is expected to provide scientific advice for CO 2 capture, flooding, and storage technologies.

Topics & Concepts

Petroleum engineeringScope (computer science)Enhanced oil recoveryUnconventional oilFossil fuelEnvironmental scienceEmerging technologiesProduction (economics)Tight oilCarbon sequestrationEngineeringComputer scienceCarbon dioxideWaste managementOil shaleEconomicsMacroeconomicsProgramming languageArtificial intelligenceBiologyEcologyCO2 Sequestration and Geologic InteractionsEnhanced Oil Recovery TechniquesHydraulic Fracturing and Reservoir Analysis