Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids

Kelvin Abaa, John Yilin Wang, Derek Elsworth, Mku Ityokumbul

Research output: Contribution to conferencePaper

Abstract

Improper selection and design of surfactant treatments intended to remove damage aqueous phase trapping often ends up causing other types of formation damage. This is due to our limited understanding of the processes that govern rock-fluid and fluid-fluid interactions between surfactants, fracturing fluid and the formation during invasion and flowback of the injected fluids in the rock matrix. This study focuses on the laboratory investigation of the processes governing multiphase permeability evolution during invasion of fracturing fluids treated with surfactants in low permeability sandstones. Two surfactant chemicals, Triton X-100, a hydrocarbon surfactant and Novec FC-4430, a fluorosurfactant, were used to treat filtrate from slickwater, linear gel and borate crosslinked gel fluids. Multiphase experiments were conducted on sandstones cores flooded with the treated fluids. The experiments consist of steady state gas displacements and pulse decay permeability measurements. The obtained data include gas flow rate, pore volumes of liquid expelled and gas relative permeability curves. Experimental results indicate that treatments with fluorosurfactant improved liquid and gas permeability recovery for all fracturing fluids. Additionally, maximum liquid and gas permeability recovery was achieved when the core was pretreated with fluorosurfactant. Our results show that multiphase permeability evolution with surfactant treatment is driven by wettability alterations rather than reduction in interfacial tension. Multiphase permeability data could be used in modeling of post fracture well performance and formation damage assessment in low permeability sandstones. The new findings will serve as a guide for optimizing fracturing fluid/surfactant treatment in tight gas reservoirs.

Original languageEnglish (US)
StatePublished - Jan 1 2019
EventSPE Western Regional Meeting 2019, WRM 2019 - San Jose, United States
Duration: Apr 23 2019Apr 26 2019

Conference

ConferenceSPE Western Regional Meeting 2019, WRM 2019
CountryUnited States
CitySan Jose
Period4/23/194/26/19

Fingerprint

Sandstone
Surface active agents
Fracturing fluids
Fluids
Gas permeability
Liquids
Gels
Rocks
Recovery
Gases
Flow of gases
Surface tension
Wetting
Experiments
Hydrocarbons
Flow rate

All Science Journal Classification (ASJC) codes

  • Energy Engineering and Power Technology

Cite this

Abaa, K., Wang, J. Y., Elsworth, D., & Ityokumbul, M. (2019). Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids. Paper presented at SPE Western Regional Meeting 2019, WRM 2019, San Jose, United States.
Abaa, Kelvin ; Wang, John Yilin ; Elsworth, Derek ; Ityokumbul, Mku. / Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids. Paper presented at SPE Western Regional Meeting 2019, WRM 2019, San Jose, United States.
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Abaa, K, Wang, JY, Elsworth, D & Ityokumbul, M 2019, 'Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids', Paper presented at SPE Western Regional Meeting 2019, WRM 2019, San Jose, United States, 4/23/19 - 4/26/19.

Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids. / Abaa, Kelvin; Wang, John Yilin; Elsworth, Derek; Ityokumbul, Mku.

2019. Paper presented at SPE Western Regional Meeting 2019, WRM 2019, San Jose, United States.

Research output: Contribution to conferencePaper

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Abaa K, Wang JY, Elsworth D, Ityokumbul M. Multiphase permeability evolution in low permeability sandstones from surfactant-treated fractring fluids. 2019. Paper presented at SPE Western Regional Meeting 2019, WRM 2019, San Jose, United States.