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Wettability alteration of carbonate rock mediated by biosurfactant produced from high-starch agricultural effluents. University of Kansas: Mehdi Salehi, Stephen Johnson and Jenn-Tai Liang Idaho National Laboratory: Sandra Fox and Gregory Bala 9 th International Wettability Symposium
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Wettability alteration of carbonate rock mediated by biosurfactant produced from high-starch agricultural effluents University of Kansas: Mehdi Salehi, Stephen Johnson and Jenn-Tai Liang Idaho National Laboratory: Sandra Fox and Gregory Bala 9th International Wettability Symposium Bergen, Norway. 18-19 September 2006
Outline • Introduction • Surfactin and benchmark surfactants • Static adsorption • Aging procedure • Wettability tests • Conclusions • Future and ongoing work • Acknowledgments
Introduction • Spontaneous imbibition of water is the main production mechanism in naturally fractured reservoirs (NFR) • NFRs are mostly oil-wet or mixed-wet (Roehl et al. 1985). • Secondary production is very low, especially if the fractures form a connected network (Allan et al. 2003) • Low-concentration surfactants can change the wettability of the reservoir rock to a more water-wet state, promoting the spontaneous imbibition of water • Cheap biosurfactant may be an economical option
Oil Surfactant • Effectiveness of surfactant-based EOR depends on surfactant propagation through reservoir • Dilute solutions of biosurfactant assessed for: • effectiveness in mediating wettability of carbonate rocks • adsorption • Compared to similar benchmark chemical surfactant
Biosurfactant • Surfactin • anionic cyclic lipopeptide • surfactant and antibiotic properties • Bacillus subtilis • grow on high-starch medium (agro-industry waste stream) • centrifuge to remove cells • HCl to precipitate surfactin • centrifuge and freeze-dry • re-dissolve in RO-water as required • Characterized by Schaller et al. (INL)
Benchmark chemical surfactants • Similar charge • Comparable tail length • Prior study and/or use • Candidates: • sodium dodecylbenzene sulfonate (BIO-SOFT D40) • sodium dodecyl sulfate (STEPANOL) • sodium laureth sulfate (STEOL CS-330)
IFT between surfactants and Soltrol 130 Selecting the chemical surfactant
Materials • Benchmark surfactant: STEOL CS-330 (Stepan Co.) • Biosurfactant: Crude surfactin (INL) • Adsorbents (53 to 300 m) : • Miami oolitic outcrop (MI) • Bethany Falls oomoldic outcrop (BF) • Lansing-Kansas City oomoldic reservoir material (L7) from the Hall-Gurney Field in Russell County, KS. • Surfactant-ion selective combination electrode used to determine concentration of anionic surfactants in aqueous solution by potentiometric titration with Hyamine 1622.
Potentiometric titration Modified after DIN EN 14480
A C B Surfactant electrode .
Static adsorption • Procedure: • 2.0 g crushed rock • 30 ml surfactant solution • shake for 24 h • centrifuge @ 3000 rpm for 30 min. • measure surfactant concentration before and after equilibrating with crushed rock • calculate specific adsorption (mg/g)
Specific adsorption at various surfactant/adsorbent mass ratios
STEOL and surfactin (30 ml) adsorption isotherms on 2.0 g BF and L7 rocks STEOL and surfactin isotherms on 2.0 g BF and L7 rocks .
Adsorption results (I) • Higher adsorption on oomoldic material • higher specific surface area • Specific adsorption as rock mass • settling of crushed rock in the test tubes reduced contact with surfactant? • higher shaking rates adsorption • mechanical scouring of surface
Adsorption results (II) • Specific adsorption • surfactin > STEOL CS-330 • maximum adsorption density reached at a lower concentration • reflects the lower CMC of surfactin • Surfactin and STEOL CS-330 on both L7 and BF rocks exhibit the four regions seen in a typical adsorption isotherm
Regions of typical adsorption isotherm Four regions of adsorption isotherm CMC . HMC After Tabatabai et al. (1993)
Explanation for regions of adsorption isotherms After Somasunduran et al. in Sharma (1995)
Wettability change • Clean crushed rocks • THF, chloroform, methanol, water • strongly water-wet • Age crushed rocks in crude oil • two weeks at 90C • strongly oil-wet • Change in wettability due to surfactants • contact aged rock with surfactants • assess wettability
Qualitative wettability tests • Two-phase separation (Somasundaran & Zhang 1997) • 0.2 g of crushed rock • 20 ml RO-water • 20 ml Soltrol 130 • shake for 1 min by hand and allow to settle • material partitions between aqueous/non-aqueous phases • Flotation test (Wu et al. 2006) • 0.2 g of crushed rock • RO-water • oil-wet material floats
LKC reservoir rock – two-phase separation and flotation tests
Bethany Falls oomoldic outcrop - two-phase separation and flotation tests .
Wettability tests results • Two-phase separation and flotation tests agree • Surfactin more effective than STEOL CS-330 in reversing the wettability of oil-wet crushed carbonate rocks.
Conclusions • Standardize and report mass of rock and volume of surfactant solution used to develop adsorption isotherms • STEOL CS-330 and surfactin exhibit typical adsorption isotherms with four distinct regions • Surfactin has higher specific adsorption on carbonate rocks than STEOL CS-330 • Surfactin is more effective than STEOL CS-330 in altering wettability of crushed BF and LKC carbonates from oil-wet to water-wet state. • on both molar and w/w bases
Ongoing and future work • Ongoing • Assess other chemical surfactants • Spontaneous/forced imbibition in cores • Future • Dynamic adsorption/desorption experiments • Economic analysis
Acknowledgements • Co-authors: • Mehdi Salehi (PhD candidate, KU) • Jenn-Tai Liang (PI, KU) • Gregory Bala (Co-PI, INL) • Sandra Fox (INL) • Other team members • Karl Eisert (MS candidate, KU) • Vivian Lopez (Undergraduate, KU) • Financial support • Grant # DE-FC26-04NT15523 • United States Department of Energy (National Energy Technology Laboratory/Strategic Center for Natural Gas and Oil)
Contact details • Stephen J. Johnson • The University of Kansas Tertiary Oil Recovery Project Learned Hall, Room 4165E 1530 W. 15th Street Lawrence, KS 66045-7609 • +1 (785) 864-3654 • +1 (785) 864-4967 • sjohn@ku.edu