Page 200 - Formation Damage during Improved Oil Recovery Fundamentals and Applications

P. 200

174 Thomas Russell et al.

Sharma, M.M., Chamoun, H., Sarma, D.S.R., Schechter, R.S., 1992. Factors controlling
the hydrodynamic detachment of particles from surfaces. J. Colloid. Interface. Sci.
149 (1), 121 134.
Shen, W., 2016. On the Cauchy problems for polymer flooding with gravitation. Journal
of differential equations. 261 (1), 627 653.
Tufenkji, N., 2007. Colloid and microbe migration in granular experiments: a discussion
of modelling methods. In: Frimmel, F.H., von der Kammer, F., Flemming, F.C.
(Eds.), Colloidal Transport in Porous Media. Springer-Verlag, Berlin.
Vaz, A., Bedrikovetsky, P., Fernandes, P., Badalyan, A., Carageorgos, T., 2017.
Determining model parameters for non-linear deep-bed filtration using laboratory
pressure measurements. J. Pet. Sci. Eng. 151, 421 433.
Verwey, E.J.W., Overbeek, J.T.G., Overbeek, J.T.G., 1999. Theory of the Stability of
Lyophobic Colloids. Dover Publications, Mineola, New York, USA.
Wang, J., Liu, Hq, Zhang, Hl, Sepehrnoori, K., 2017. Simulation of deformable pre-
formed particle gel propagation in porous media. AIChE. J. 63 (10), 4628 4641.
Yang, H., Balhoff, M.T., 2017. Pore-network modeling of particle retention in porous
media. AIChE. J. 63 (7), 3118 3131.
Yang, Y., Bedrikovetsky, P., 2017. Exact solutions for nonlinear high retention-
concentration fines migration. Trans. Porous. Media. 119 (2), 351 372.
Yang, Y., Siqueira, F.D., Vaz, A.S., You, Z., Bedrikovetsky, P., 2016. Slow migration of
detached fine particles over rock surface in porous media. J. Nat. Gas. Sci. Eng. 34,
1159 1173.
You, Z.,Badalyan, A.,Yang, Y.,Bedrikovetsky,P., Hand,M., 2014. Laboratory study offines
migration in geothermal reservoirs. Geothermics (submitted for publication).
You, Z., Yang, Y., Badalyan, A., Bedrikovetsky, P., Hand, M., 2016. Mathematical model-
ling of fines migration in geothermal reservoirs. Geothermics 59, 123 133.
Yuan, B., Moghanloo, R.G., 2017. Analytical model of well injectivity improvement
using nanofluid preflush. Fuel 202, 380 394.
Yuan, B., Moghanloo, R.G., Zheng, D., 2016. Analytical evaluation of nanoparticle
application to mitigate fines migration in porous media. SPE. J. 21 (06), 2317 2332.
Yuan, B., Moghanloo, R., Wang, W., 2018a. Using nanofluids to control fines migration
for oil recovery: nanofluids co-injection or nanofluids preflush? a comprehensive
answer. Fuel 215, 474 48312.
Yuan, B., Moghanloo, R., 2018b. Nanofluid treatment, an effective approach to improve
performance of low salinity water flooding. J. Pet. Sci. Eng. in press
Available from: https://doi.org/10.1016/j.petrol.2017.11.032.
Yuan, B., Moghanloo, R.G., 2018c. Nanofluid pre-coating, an effective method to reduce
fines migration in radial systems saturated with mobile immiscible fluids. SPE J.,
SPE-189464-PA. https://doi.org/10.2118/189464-PA
Yuan, H., Shapiro, A.A., 2010. Modeling non-Fickian transport and hyperexponential
deposition for deep bed filtration. Chem. Eng. J. 162 (3), 974 988.
Yuan, H., Shapiro, A.A., 2011. Induced migration of fines during waterflooding in com-
municating layer-cake reservoirs. J. Pet. Sci. Eng. 78 (3), 618 626.
Zeinijahromi, A., Bedrikovetsky, P., 2016. Water production control using low-salinity
water injection. SPE Asia Pacific Oil & Gas Conference and Exhibition. Society of
Petroleum Engineers, Perth, Australia.
Zeinijahromi, A., Lemon, P., Bedrikovetsky, P., 2011. Effects of induced fines migration
on water cut during waterflooding. J. Pet. Sci. Eng. 78 (3), 609 617.
Zeinijahromi, A., Vaz, A., Bedrikovetsky, P., 2012a. Well impairment by fines migration
in gas fields. J. Pet. Sci. Eng. 88, 125 135.
Zeinijahromi, A., Vaz, A., Bedrikovetsky, P., Borazjani, S., 2012b. Effects of fines migration
on well productivity during steady state production. J. Porous. Media. 15 (7), 665 679.

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