**Chapter 8**

*Analytical Chemistry - Advancement, Perspectives and Applications*

Surfactants for Enhanced Oil Recovery

Applications. 2020:89-102

[39] Azam MR, Tan IM, Ismail L, Mushtaq M, Nadeem M, Sagir M. Static adsorption of anionic surfactant onto crushed Berea sandstone. Journal of Petroleum Exploration and Production

Technology. 2013;**3**(3):195-201

Petroleum Engineers. 2014

2014;**1621**(1):699-704

[40] Sagir M, Tan IM, Mushtaq M, Talebian SH. FAWAG using CO2 philic surfactants for CO2 mobility control for enhanced oil recovery applications. In: SPE Saudi Arabia Section Technical Symposium and Exhibition. Society of

[41] Sagir M, Tan IM, Mushtaq M. CO2 philic surfactant as possible mobility control agent in EOR applications. AIP Conference Proceedings. American Institute of Physics.

[42] Sagir M, Tan IM, Mushtaq M, Talebian SH. Static adsorption of new CO2 philic surfactant onto Berea sandstone. In: ICIPEG 2014; Springer,

[43] Sagir DM, Tahir MS. CO2 foam for CO2 mobility control using a unique surfactant structure for EOR applications. In: 2nd International Conference on Engineering Sciences.

[44] Sagir M, Mushtaq M, Tahir MS, Tahir MB, Shaik AR. CO2 philic surfactants, switchable amine-based surfactants and wettability alteration for EOR applications. In: Surfactants for Enhanced Oil Recovery Applications. Cham: Springer; 2020. pp. 89-102

[45] Sagir M, Talebian SH. Screening of CO2-philic surfactants morphology for high temperature-pressure sandstone reservoir conditions. Journal of Petroleum Science and Engineering.

2020;**186**:106789

Singapore. 2015. pp. 129-135

2015

foam for enhanced oil recovery (EOR) applications using low adsorption surfactant structure. Arabian Journal of

[32] Sami U, Humbul S, Suleman TM,

Al-Sehemi AG, et al. Reactive kinetics of carbon dioxide loaded aqueous blend of 2-amino-2-ethyl-1,3-propanediol and piperazine using a pressure drop method. International Journal of Chemical Kinetics. 2019;**51**(4):291-298

[33] Farzaneh SA, Sohrabi M. A review of the status of foam application in enhanced oil recovery. Presented at the

[34] Xing D, Wei B, McLendon WJ, Enick RM, McNulty S, Trickett K, et al. CO2-soluble, nonionic, water-soluble surfactants that stabilize CO2-in-brine

[35] Sami U, Azmi BM, Ali AM,

Firas AA, et al. Synthesis, and characterization of metal-organic frameworks-177 for static and dynamic adsorption behavior of CO2 and CH4. Microporous and Mesoporous Materials.

[36] Bilal TM, Muhammad S, Naeem A. Enhanced photocatalytic performance of CdO-WO3 composite for hydrogen production. International

Journal of Hydrogen Energy. 2019;**44**(45):24690-24697

[37] Muhammad S, Hosna TS. Screening of CO2-philic surfactants morphology for high temperature-pressure

sandstone reservoir conditions. Journal of Petroleum Science and Engineering.

[38] Muhammad S, Muhammad M, Suleman TM, Bilal TM, Ravoof SA. CO2-philic surfactants, switchable amine-based surfactants and wettability

alteration for EOR applications.

Al-Sehemi AG, Muhammad S, Kareem

Geosciences. 2018;**11**(24):789

Muhammad S, Shabbir M,

SPE-164917-MS. 2013

foams. 2012

2019;**288**:109569

2020;**106789**:186

**150**
