COSMO-RS: An ionic liquid prescreening tool for gas hydrate mitigation

doi:10.1016/j.cjche.2016.07.014

Abstract

Abstract: Recently ionic liquids (ILs) are introduced as novel dual function gas hydrate inhibitors. However, no desired gas hydrate inhibition has been reported due to poor IL selection and/or tuning method. Trial & error as well as selection based on existing literature are the methods currently employed for selecting and/or tuning ILs. These methods are probabilistic, time consuming, expensive and may not result in selecting high performance ILs for gas hydrate mitigation. In this work, COSMO-RS is considered as a prescreening tool of ILs for gas hydrate mitigation by predicting the hydrogen bonding energies (E_HB) of studied IL inhibitors and comparing the predicted E_HB to the depression temperature (?) and induction time. Results showthat, predicted E_HB and chain length of ILs strongly relate and significantly affect the gas hydrate inhibition depression temperature but correlate moderately (R=0.70) with average induction time in literature. It is deduced fromthe results that, ? increaseswith increasing IL E_HB and/or decreases with increasing chain length. However, the cation-anion pairing of ILs also affects IL gas hydrate inhibition performance. Furthermore, a visual and better understanding of IL/water behavior for gas hydrate inhibition in terms of hydrogen bond donor and acceptor interaction analysis is also presented by determining the sigma profile and sigma potential of studied IL cations and anions used for gas hydrate mitigation for easy IL selection.

Key words: Gas hydrates, COSMO-RS, Hydrogen bonding energies, Ionic liquids, Tuning

摘要： Recently ionic liquids (ILs) are introduced as novel dual function gas hydrate inhibitors. However, no desired gas hydrate inhibition has been reported due to poor IL selection and/or tuning method. Trial & error as well as selection based on existing literature are the methods currently employed for selecting and/or tuning ILs. These methods are probabilistic, time consuming, expensive and may not result in selecting high performance ILs for gas hydrate mitigation. In this work, COSMO-RS is considered as a prescreening tool of ILs for gas hydrate mitigation by predicting the hydrogen bonding energies (E_HB) of studied IL inhibitors and comparing the predicted E_HB to the depression temperature (?) and induction time. Results showthat, predicted E_HB and chain length of ILs strongly relate and significantly affect the gas hydrate inhibition depression temperature but correlate moderately (R=0.70) with average induction time in literature. It is deduced fromthe results that, ? increaseswith increasing IL E_HB and/or decreases with increasing chain length. However, the cation-anion pairing of ILs also affects IL gas hydrate inhibition performance. Furthermore, a visual and better understanding of IL/water behavior for gas hydrate inhibition in terms of hydrogen bond donor and acceptor interaction analysis is also presented by determining the sigma profile and sigma potential of studied IL cations and anions used for gas hydrate mitigation for easy IL selection.

关键词: Gas hydrates, COSMO-RS, Hydrogen bonding energies, Ionic liquids, Tuning

Cornelius B. Bavoh, Bhajan Lal, Omar Nashed, Muhammad S. Khan, Lau K. Keong, Mohd. Azmi Bustam. COSMO-RS: An ionic liquid prescreening tool for gas hydrate mitigation[J]. Chin.J.Chem.Eng., 2016, 24(11): 1619-1624.

Cornelius B. Bavoh, Bhajan Lal, Omar Nashed, Muhammad S. Khan, Lau K. Keong, Mohd. Azmi Bustam. COSMO-RS: An ionic liquid prescreening tool for gas hydrate mitigation[J]. Chinese Journal of Chemical Engineering, 2016, 24(11): 1619-1624.

References

[1] E.D. Sloan, C.A. Koh, Clathrate hydrates of natural gases, third ed. CRC Press, Baca Raton, 2007.
[2] C.A. Koh, E.D. Sloan, A.K. Sum, D.T. Wu, Fundamentals and applications of gas hydrates, Annu. Rev. Chem. Biomol. Eng. 2(2011) 237-257.
[3] C. Sun,W. Li, X. Yang, F. Li, Q. Yuan, L. Mu, et al., Progress in research of gas hydrate, Chin. J. Chem. Eng. 19(2011) 151-162.
[4] X. Peng, Y. Hu, L. Yang, C. Jin, Decomposition kinetics for formation of CO₂ hydrates in natural silica sands, Chin. J. Chem. Eng. 18(2010) 61-65.
[5] L. Chen, C. Sun, G. Chen, Y. Nie, Z. Sun, Y. Liu, Measurements of hydrate equilibrium conditions for CH₄, CO₂, and CH₄+C₂H₆+C₃H₈ in various systems by step-heating method, Chin. J. Chem. Eng. 17(2009) 635-641.
[6] X. Sen Li, Y.J. Liu, Z.Y. Zeng, Z.Y. Chen, G. Li, H.J. Wu, Equilibrium hydrate formation conditions for the mixtures of methane + ionic liquids + water, J. Chem. Eng. Data 56(2011) 119-123.
[7] M. Tariq, D. Rooney, E. Othman, S. Aparicio, M. Atilhan, M. Khraisheh, Gas hydrate inhibition:A review of the role of ionic liquids, Ind. Eng. Chem. Res. 53(2014) 17855-17868.
[8] J. Carroll, Natural gas hydrates a guide for engineers, Elsevier, Third edit, 2014.
[9] C. Xiao, H. Adidharma, Dual function inhibitors for methane hydrate, Chem. Eng. Sci. 64(2009) 1522-1527.
[10] C. Xiao, N. Wibisono, H. Adidharma, Dialkylimidazolium halide ionic liquids as dual function inhibitors for methane hydrate, Chem. Eng. Sci. 65(2010) 3080-3087.
[11] M. Zare, A. Haghtalab, A.N. Ahmadi, K. Nazari, Experiment and thermodynamic modeling of methane hydrate equilibria in the presence of aqueous imidazoliumbased ionic liquid solutions using electrolyte cubic square well equation of state, Fluid Phase Equilib. 341(2013) 61-69.
[12] K.M. Sabil, O. Nashed, B. Lal, L. Ismail, A. Japper-jaafar, Experimental investigation on the dissociation conditions of methane hydrate in the presence of imidazoliumbased ionic liquids, Thermodyn. J. Chem. 84(2015) 7-13.
[13] B. Partoon, N.M.S. Wong, K.M. Sabil, K. Nasrifar, M.R. Ahmad, A study on thermodynamics effect of[EMIM]-Cl and[OH-C₂MIM]-Cl on methane hydrate equilibrium line, Fluid Phase Equilib. 337(2013) 26-31.
[14] K. Nazari, A.N. Ahmadi, A thermodynamic study of methane hydrate formation in the presence of[Bmim] [Bf 4] and[Bmim] [Ms] ionic liquids, I7th Intenational Confrence Gas Hydrates 2011, Edinbrugh, Scotland, United Kingdom 2011, p. 9.
[15] T. Makino, Y. Matsumoto, T. Sugahara, K. Ohgaki, H.Masuda, Effect of ionic liquid on hydrate formation rate in carbon dioxide hydrates, Proc. 7th Int. Conf. Gas Hydrates (ICGH), Edinburgh, Scotland, United Kingdom 2011, pp. 2-5.
[16] K. Tumba, P. Reddy, P. Naidoo, D. Ramjugernath, A. Eslamimanesh, A.H. Mohammadi, et al., Phase equilibria of methane and carbon dioxide clathrate hydrates in the presence of aqueous solutions of tributylmethylphosphonium methylsulfate ionic liquid, J. Chem. Eng. Data 56(2011) 3620-3629.
[17] T. Kitajima, N. Ohtsubo, S. Hashimoto, T. Makino, D. Kodama, K. Ohgaki, Study on prompt methane hydrate formation derived by addition of ionic liquid, Am. Chem. Sci. J. 2(2012) 100-110.
[18] K. Kim, S.-P. Kang, Investigation of pyrrolidinium-andmorpholinium-based ionic liquids into kinetic hydrate inhibitors on structure i methane hydrate, 7th Intenational Confrence Gas Hydrates 2011, Edinbrugh, Scotland, United Kingdom 2011, p. 6.
[19] B. Lal, M. Sahin, E. Ayranci, Volumetric studies to examine the interactions of imidazolium based ionic liquids with water by means of density and speed of sound measurements, J. Chem. Thermodyn. 54(2012) 142-147.
[20] H. Jiang, H. Adidharma, Thermodynamic modeling of aqueous ionic liquid solutions and prediction of methane hydrate dissociation conditions in the presence of ionic liquid, Chem. Eng. Sci. 102(2013) 24-31.
[21] M. Ebrahim, H. Nasrollah, B. Abareshi, C. Ghotbi, V. Taghikhani, A.H. Jalili, et al., Investigation of six imidazolium-based ionic liquids as thermo-kinetic inhibitors for methane hydrate by molecular dynamics simulation, Proc. 2nd Natl. Iran. Conf. Gas Hydrate 2013, p. 12.
[22] A. Klamt, F. Eckert, COSMO-RS:a novel and efficient method for the a priori prediction of thermophysical data of liquids, Fluid Phase Equilib. 172(2000) 43-72.
[23] A. Klamt, The COSMO and COSMO-RS solvation models, Wiley Interdiscip. Rev. Comput. Mol. Sci. 1(2011) 699-709.
[24] U. Guide, A graphical user interface to the COSMOtherm, Program (2012) 1-77.
[25] L.S. Ferreira, J.O. Trierweiler,Modeling and simulation of the polymeric nanocapsule formation process, IFAC Proc. 7(2009) 405-410.
[26] A.R. Ferreira, M.G. Freire, J.C. Ribeiro, F.M. Lopes, G. Crespo, Overview of the liquid-liquid equilibria of ternary systems composed of ionic liquid and aromatic and aliphatic hydrocarbons, and their modeling by COSMO-RS, Ind. Eng. Chem. Res. 51(2012) 3483-3507.
[27] D.I.W. Edward, M. Ishiyama, W.R. Paterson, Modeling and simulation of the polymeric nanocapsule formation process, AIChE J. 57(2011) 3199-3209.
[28] Z. Lei, B. Zhang, J. Zhu,W. Gong, J. Lü, Y. Li, Solubility of CO₂ in methanol, 1-octyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide, and their mixtures, Chin. J. Chem. Eng. 21(2013) 310-317.
[29] R. Kato, J. Gmehling, Systems with ionic liquids:measurement of VLE and γ∞ data and prediction of their thermodynamic behavior using original UNIFAC, mod. UNIFAC(Do) and COSMO-RS(Ol), J. Chem. Thermodyn. 37(2005) 603-619.
[30] K.Z. Sumon, A. Henni, Ionic liquids for CO₂ capture using COSMO-RS:effect of structure, properties and molecular interactions on solubility and selectivity, Fluid Phase Equilib. 310(2011) 39-55.
[31] J. Palomar, V.R. Ferro, J.S. Torrecilla, F. Rodríguez, Density and molar volume predictions using COSMO-RS for ionic liquids. An approach to solvent design, Ind. Eng. Chem. Res. 46(2007) 6041-6048.
[32] G. Gonfa, M.A. Bustam, A.M. Sharif, N. Mohamad, S. Ullah, Tuning ionic liquids for natural gas dehydration using COSMO-RS methodology, J. Nat. Gas Sci. Eng. (2015).
[33] A.F.M. Cláudio, L. Swift, J.P. Hallett, T. Welton, J.a.P. Coutinho, M.G. Freire, Extended scale for the hydrogen-bond basicity of ionic liquids, Phys. Chem. Chem. Phys. 16(2014) 6593-6601.
[34] M.H. Hao, Theoretical calculation of hydrogen-bonding strength for drugmolecules, J. Chem. Theory Comput. 2(2006) 863-872.
[35] M.H. Abraham, P.L. Grellier, R.M. Doherty, R.W. Taft, The use of scales of hydrogenbond acidity and basicity in organic, Rev. Port. Quim. 31(1989).
[36] A. Klamt, COSMO-RS for aqueous solvation and interfaces, fluid phase equilib, 2015.
[37] H. Ohno, K. Fukumoto, Amino acid ionic liquids, Acc. Chem. Res. 40(2007) 1122-1129.