A short review on natural gas hydrate, kinetic hydrate inhibitors and inhibitor synergists

doi:10.1016/j.cjche.2018.10.010

Abstract

Abstract: Gas hydrate-caused pipeline plugging is an industrial nuisance for petroleum flow assurance that calls for technological innovations. Traditional thermodynamic inhibitors such as glycols and inorganic salts suffer from high dosing, environmental unfriendliness, corrosiveness, and economical burden. The development and use of kinetic hydrate inhibitors (KHIs), mostly polymeric compounds, with their inhibiting effects on hydrate nucleation and growth are considered an effective and economically viable chemical treatment for hydrate prevention. However, the actual performance of a KHI candidate is dependent on various factors including its chemical structure, molecular weight, spatial configuration, effective concentration, pressure and temperature, evaluation methods, use of other additives, etc. This review provides a short but systematic overview of the fundamentals of natural gas hydrates, the prevailing categories of polymeric kinetic hydrate inhibitors with proposed inhibition mechanisms, and the various synergists studied for boosting the KHI performance. Further research endeavors are in need to unveil the KHI working modes under different conditions. The conjunctive use of KHIs and synergists may facilitate the commercial application of effective KHIs to tackle the hydrate plugging problem in the oil and gas flow assurance practices.

Key words: Hydrate, Nucleation, Kinetics, Hydrate inhibitors, Inhibition mechanism, Inhibitor synergist

摘要： Gas hydrate-caused pipeline plugging is an industrial nuisance for petroleum flow assurance that calls for technological innovations. Traditional thermodynamic inhibitors such as glycols and inorganic salts suffer from high dosing, environmental unfriendliness, corrosiveness, and economical burden. The development and use of kinetic hydrate inhibitors (KHIs), mostly polymeric compounds, with their inhibiting effects on hydrate nucleation and growth are considered an effective and economically viable chemical treatment for hydrate prevention. However, the actual performance of a KHI candidate is dependent on various factors including its chemical structure, molecular weight, spatial configuration, effective concentration, pressure and temperature, evaluation methods, use of other additives, etc. This review provides a short but systematic overview of the fundamentals of natural gas hydrates, the prevailing categories of polymeric kinetic hydrate inhibitors with proposed inhibition mechanisms, and the various synergists studied for boosting the KHI performance. Further research endeavors are in need to unveil the KHI working modes under different conditions. The conjunctive use of KHIs and synergists may facilitate the commercial application of effective KHIs to tackle the hydrate plugging problem in the oil and gas flow assurance practices.

关键词: Hydrate, Nucleation, Kinetics, Hydrate inhibitors, Inhibition mechanism, Inhibitor synergist

Wei Ke, Daoyi Chen. A short review on natural gas hydrate, kinetic hydrate inhibitors and inhibitor synergists[J]. Chinese Journal of Chemical Engineering, 2019, 27(9): 2049-2061.

Wei Ke, Daoyi Chen. A short review on natural gas hydrate, kinetic hydrate inhibitors and inhibitor synergists[J]. 中国化学工程学报, 2019, 27(9): 2049-2061.

References

[1] E.D. Sloan, Fundamental principles and applications of natural gas hydrates, Nature 426(2003) 353-363.
[2] C.A. Koh, A.K. Sum, E.D. Sloan, State of the art:Natural gas hydrates as a natural resource, J. Nat. Gas Sci. Eng. 8(2012) 132-138.
[3] T. Collett, J.-J. Bahk, R. Baker, R. Boswell, D. Divins, M. Frye, D. Goldberg, J. Husebø, C.A. Koh, M. Malone, M. Morell, G. Myers, C. Shipp, M. Torres, Methane hydrates in nature-current knowledge and challenges, J. Chem. Eng. Data 60(2) (2015) 319-329.
[4] K.A. Kvenvolden, T.D. Lorenson, The Global Occurrence of Natural Gas Hydrate, American Geophysical Union, Washington, D. C., 2001
[5] A.V. Milkov, Global estimates of hydrate-bound gas in marine sediments:How much is really out there? Earth-Sci. Rev. 66(3-4) (2004) 183-197.
[6] Z. Chong, S.H.B. Yang, P. Babu, P. Linga, X. Li, Review of natural gas hydrates as an energy resource:Prospects and challenges, Appl. Energy 162(2016) 1633-1652.
[7] B. Kvamme, Symposium on natural gas hydrates:A future climate bomb or a valuable source of energy? Opportunities and challenges for the computational physics community, AIP Conf. Proc. 1504(2012) 754.
[8] Z. Zhang, Y. Wang, L. Gao, Y. Zhang, C. Liu, Marine gas hydrates:Future energy or environmental killer? Energy Procedia 16(2012) 933-938.
[9] M. Giustiniani, U. Tinivella, M. Jakobsson, M. Rebesco, Arctic Ocean gas hydrate stability in a changing climate, J. Geol. Res. 2013(2013), 783969.
[10] D. Archer, Methane hydrate stability and anthropogenic climate change, Biogeosciences 4(4) (2007) 521-544.
[11] J. Henriet, J. Mienert, Gas hydrates:Relevance to world margin stability and climate change, Geol. Soc. Lond. Spec. Publ. 137(1998) 338.
[12] M.T. Reagan, G.J. Moridis, Oceanic gas hydrate instability and dissociation under climate change scenarios, Geophys. Res. Lett. 34(2007), L22709.
[13] B. Buffett, D. Archer, Global inventory of methane clathrate:Sensitivity to changes in the deep ocean, Earth Planet. Sci. Lett. 227(2004) 185-199.
[14] H. Dashti, L.Z. Yew, X. Lou, Recent advances in gas hydrate-based CO₂ capture, J. Nat. Gas Sci. Eng. 23(2015) 195-207.
[15] P. Babu, P. Linga, R. Kumar, P. Englezos, A review of the hydrate based gas separation (HBGS) process for carbon dioxide pre-combustion capture, Energy 85(2015) 261-279.
[16] C. Xu, X. Li, Research progress of hydrate-based CO₂ separation and capture from gas mixtures, RSC Adv. 4(2014) 18301-18316.
[17] R.A. McCormack, R.K. Andersen, Clathrate Desalination Plant Preliminary Research Study, US Bureau of Reclamation, Technical Services Center, Water Treatment Engineering and Research Group, 1995.
[18] L. Cai, B.A. Pethica, P.G. Debenedetti, S. Sundaresan, Formation of cyclopentane methane binary clathrate hydrate in brine solutions, Chem. Eng. Sci. 141(2016) 125-132.
[19] L. Cai, Desalination via Formation of Binary Clathrate Hydrates, PhD Thesis, Princeton University, 2016.
[20] H. Lee, J.W. Lee, D.Y. Kim, J. Park, Y.T. Seo, H. Zeng, I.L. Moudrakovski, C.I. Ratcliffe, J.A. Ripmeester, Tuning clathrate hydrates for hydrogen storage, Nature 434(7034) (2005) 743-746.
[21] L.J. Florusse, E.D. Sloan, S.F. Dec, C.A. Koh, J. Schoonman, C.J. Peters, K.N. Marsh, K.C. Hester, Stable low-pressure hydrogen clusters stored in a binary clathrate hydrate, Science 306(5695) (2004) 469-471.
[22] H.P. Veluswamy, R. Kumar, P. Linga, Hydrogen storage in clathrate hydrates:Current state of the art and future directions, Appl. Energy 122(2014) 112-132.
[23] H. Shirota, I. Aya, S. Namie, P. Bollavaram, D. Turner, E.D. Sloan, Measurement of methane hydrate dissociation for application to natural gas storage and transportation, 4th International Conference on Gas Hydrates. Yokohama, Japan 2002, pp. 972-977.
[24] Y. Nakajima, T. Takaoki, K. Ohgaki, S. Ota, Use of hydrate pellets for transportation of natural gas-II-proposition of natural gas transportation in form of hydrate pellets, Proc. 4th Int. Conf. Gas Hydrates 2002, pp. 987-990.
[25] J.S. Gudmundsson, A. Borrehaug, Frozen hydrate for transport of natural gas, in:J. Monfort (Ed.), 2nd International Conference on Natural Gas Hydrates, June 2-6, 1996, INPT-ENSIGC, Toulouse, France June 2-6, 1996, pp. 415-422.
[26] L. Fournaison, A. Delahaye, I. Chatti, J.-P. Petitet, CO₂ hydrates in refrigeration processes, Ind. Eng. Chem. Res. 43(20) (2004) 6521-6526.
[27] A.K. Sum, C.A. Koh, E.D. Sloan, Clathrate hydrates:From laboratory science to engineering practice, Ind. Eng. Chem. Res. 48(16) (2009) 7457-7465.
[28] E.D. Sloan, C.A. Koh, Clathrate Hydrates of Natural Gases, Third ed. CRC Press, 2008.
[29] M.A. Kelland, Gas hydrate control, Production Chemicals for the Oil and Gas Industry, second ed.CRC Press, Boca Raton, FL, 2014.
[30] M.A. Kelland, History of the development of low dosage hydrate inhibitors, Energy Fuels 20(3) (2006) 825-847.
[31] S. Subramanian, R.A. Kini, S.F. Dec, E.D. Sloan, Evidence of structure II hydrate formation from methane + ethane mixtures, Chem. Eng. Sci. 55(2000) 1981-1999.
[32] S. Subramanian, A.L. Ballard, R.A. Kini, S.F. Dec, E.D. Sloan, Structural transitions in methane+ethane gas hydrates-Part I:Upper transition point and applications, Chem. Eng. Sci. 55(23) (2000) 5763-5771.
[33] F. London, The general theory of molecular forces, Trans. Faraday Soc. 33(1937) 8b-26.
[34] J.N. Israelachvili, Intermolecular and Surface Forces:Revised Third Edition, Academic Press, 2011.
[35] G.H. Kwak, K.H. Lee, B.R. Lee, A.K. Sum, Quantification of the risk for hydrate formation during cool down in a dispersed oil-water system, Korean J. Chem. Eng. 34(7) (2017) 2043-2048.
[36] P. Chaudhari, L.E. Zerpa, A.K. Sum, A correlation to quantify hydrate plugging risk in oil and gas production pipelines based on hydrate transportability parameters, J. Nat. Gas Sci. Eng. 58(2018) 152-161.
[37] R.L. Christiansen, E.D. Sloan, Mechanisms and kinetics of hydrate formation, Ann. N. Y. Acad. Sci. 715(1) (1994) 283-305.
[38] E.D. Sloan, F. Fleyfel, A molecular mechanism for gas hydrate nucleation from ice, AIChE J. 37(9) (1991) 1281-1292.
[39] R. Radhakrishnan, B.L. Trout, A new approach for studying nucleation phenomena using molecular simulations:Application to CO₂ hydrate clathrates, J. Chem. Phys. 117(4) (2002) 1786-1796.
[40] J. Long, Gas Hydrate Formation Mechanism and Its Kinetic Inhibition, Ph.D. Thesis, Colorado School of Mines, Golden, CO, 1994.
[41] B. Kvamme, A unified nucleation theory for the kinetics of hydrate formation, Ann. N. Y. Acad. Sci. 912(1) (2010) 496-501.
[42] S. Ancoli-Israel, P. Gehrman, J.L. Martin, T. Shochat, M. Marler, J. Corey-Bloom, L. Levi, Increased light exposure consolidates sleep and strengthens circadian rhythms in severe Alzheimer's disease patients, Behav. Sleep Med. 1(1) (2003) 22-36.
[43] J.P. Long, E.D. Sloan, Hydrates in the ocean and evidence for the location of hydrate formation, Int. J. Thermophys. 17(1) (1996) 1-13.
[44] Y. Fujioka, K. Takeuchi, Y. Shindo, H. Komiyama, Shrinkage of liquid CO₂ droplets in water, Int. J. Energy Res. 18(8) (1994) 765-769.
[45] C. Moon, P.C. Taylor, P.M. Rodger, Molecular dynamics study of gas hydrate formation, J. Am. Chem. Soc. 125(16) (2003) 4706-4707.
[46] M.A. Kelland, A review of kinetic hydrate inhibitors-tailor-made water-soluble polymers for oil and gas industry applications, Advances in Materials Science Research, vol. 8, Nova Science Publishers, Inc, New York, 2012.
[47] Sloan, E. D., Method for controlling clathrate hydrates in fluid systems, U.S. Pat., 5420370. 1995.
[48] R. O'Reilly, N.S. Ieong, P.C. Chua, M.A. Kelland, Missing poly(N-vinyl lactam) kinetic hydrate inhibitor:High-pressure kinetic hydrate inhibition of structure II gas hydrates with poly(N-vinylpiperidone) and other poly(N-vinyl lactam) Homopolymers, Energy Fuel 25(2011) 4595-4599.
[49] Cohen, J. M., Wolf, P. F., Young, W. D., Method for preventing or retarding the formation of gas hydrates, U.S. Pat., 5723524. 1998.
[50] P.C. Chua, M.A. Kelland, Poly(N-vinyl azacyclooctanone):A more powerful structure II kinetic hydrate inhibitor than poly(N-vinyl caprolactam), Energy Fuel 26(2012) 4481-4485.
[51] D.Posteraro,J.Verrett,M.Maric,P.Servio,Newinsightsintotheeffect ofPolyvinylpyrrolidone (PVP) concentration on methane hydrate growth. 1. Growth rate, Chem. Eng. Sci. 126(2015) 99-105.
[52] D. Posteraro, J. Ivall, M. Maric, P. Servio, New insights into the effect of Polyvinylpyrrolidone (PVP) concentration on methane hydrate growth. 2. Liquid phase methane mole fraction, Chem. Eng. Sci. 126(2015) 91-98.
[53] Klomp, U.C., Method for inhibiting the plugging of conduits by gas hydrates, International Pat., WO/2001/077270. 2001.
[54] P.C. Chua, M.A. Kelland, K. Ishitake, K. Satoh, M. Kamigaito, Y. Okamoto, Kinetic hydrate inhibition of poly(N-isopropylmethacrylamide)s with different Tacticities, Energy Fuel 26(2012) 3577-3585.
[55] Carlise, J. R., Lindeman, O. E. S., Reed, P. E., Conrad, P. G., Ver Vers, L.M., Method of controlling gas hydrates in fluid systems, International Pat., WO/2010/045520. 2010.
[56] Colle, K. S., Oelfke, R.H., A method for inhibiting hydrate formation, International Pat., WO/1996/008673. 1996.
[57] L.D. Villano, R. Kommedal, M.W.M. Fijten, U.S. Schubert, R. Hoogenboom, M.A. Kelland, A study of the kinetic hydrate inhibitor performance and seawater biodegradability of a series of poly(2-alkyl-2-oxazoline)s, Energy Fuel 23(7) (2009) 3665-3675.
[58] Leinweber, D., Roesch, A., Feustel, M., Use of substituted polyethyleneimines as gas hydrate inhibitors with improved biodegradability, U.S. Pat., 20090054268. 2009.
[59] Leinweber, D., Feustel, M., Use of pyroglutamic acid esters as gas hydrate inhibitors with improved biodegradability, International Pat., WO/2007/054226. 2007.
[60] Colle, K. S., Costello, C. A., Talley, L.D., Method for inhibiting hydrate formation, Canadian Pat., 96/2178371. 1996.
[61] Klug, P., Kelland, M.A., Additives for inhibiting formation of gas hydrates, International Pat., WO/1998/023843. 1998.
[62] P.C. Chua, M. Sæbø, A. Lunde, M.A. Kelland, Dual kinetic hydrate inhibition and scale inhibition by Polyaspartamides, Energy Fuel 25(11) (2011) 5165-5172.
[63] L.D. Villano, R. Kommedal, M.A. Kelland, Class of kinetic hydrate inhibitors with good biodegradability, Energy Fuel 2(2008) 3143-3149.
[64] Kelland, M.A., Additives for inhibiting gas hydrate formation, International Pat., WO/2008/023989. 2008.
[65] Colle, K. S., Costello, C. A., Berluche, E., Oelfke, R. H., Talley, L.D., Polymers for use as hydrate inhibitors, International Pat., WO/1996/041834. 1996.
[66] M.R. Talaghat, Experimental investigation of gas consumption for simple gas hydrate formation in a recirculation flow mini-loop apparatus in the presence of modified starch as a kinetic inhibitor, J. Nat. Gas Sci. Eng. 14(2013) 42-48.
[67] J.D. Lee, H. Wu, P. Englezos, Cationic starches as gas hydrate kinetic inhibitors, Chem. Eng. Sci. 62(2007) 6548-6555.
[68] Z.R. Chong, A.H. Min Chan, P. Babu, M. Yang, P. Linga, Effect of NaCl on methane hydrate formation and dissociation in porous media, J. Nat. Gas Sci. Eng. 27(2015) 178-189.
[69] H. Sharifi, V.K. Walker, J.A. Ripmeester, P. Englezos, Insights into the behavior of biological clathrate hydrate inhibitors in aqueous saline solutions, Cryst. Growth Des. 14(6) (2014) 2923-2930.
[70] H. Sharifi, V.K. Walker, J.A. Ripmeester, P. Englezos, Inhibition activity of antifreeze proteins with natural gas hydrates in saline and the light crude oil mimic, heptane, Energy Fuel 28(6) (2014) 3712-3717.
[71] C.M. Perfeldt, P.C. Chua, N. Daraboina, D. Friis, E. Kristiansen, H. Ramløv, J.M. Woodley, M.A. Kelland, N. Von Solms, Inhibition of gas hydrate nucleation and growth:Efficacy of an antifreeze protein from the longhorn beetle Rhagium Mordax, Energy Fuel 28(6) (2014) 3666-3672.
[72] D. Myran, A. Middleton, J. Choi, R. Gordienko, H. Ohno, J.A. Ripmeester, V.K. Walker, Genetically-engineered mutant antifreeze proteins provide insight into hydrate inhibition, Proceedings of the 7th International Conference on Gas Hydrates, Edinburgh, Scotland, United Kingdom, 2011.
[73] H. Ohno, R. Susilo, R. Gordienko, J. Ripmeester, V.K. Walker, Interaction of antifreeze proteins with hydrocarbon hydrates, Chem. Eur. J. 16(34) (2010) 10409-10417.
[74] R. Gordienko, H. Ohno, V.K. Singh, Z. Jia, J.A. Ripmeester, V.K. Walker, Towards a green hydrate inhibitor:Imaging antifreeze proteins on clathrates, PLoS One 5(2) (2010), e8953.
[75] A. Cruz-Torres, A. Romero-Martinez, A. Galano, Computational study on the antifreeze glycoproteins as inhibitors of clathrate-hydrate formation, ChemPhysChem 9(2008) 1630-1635.
[76] V.K. Walker, H. Zeng, H. Ohno, N. Daraboina, H. Sharifi, S.A. Bagherzadeh, S. Alavi, P. Englezos, Antifreeze proteins as gas hydrate inhibitors, Can. J. Chem. 93(8) (2015) 839-849.
[77] W. Ke, M.A. Kelland, Kinetic hydrate inhibitor studies for gas hydrate systems-a review of experimental equipment and test methods, Energy Fuel 30(12) (2016) 10015-10028.
[78] W. Ke, T.M. Svartaas, J.T. Kvaløy, B.R. Kosberg, Inhibition-promotion:Dual effects of Polyvinylpyrrolidone (PVP) on structure-II hydrate nucleation, Energy Fuel 30(9) (2016) 7646-7655.
[79] T.M. Svartaas, W. Ke, S. Tantciura, A. Bratland, Penalized maximum likelihood estimation-a reliable statistical method for hydrate nucleation data analysis, Energy Fuel 29(2015) 8195-8207.
[80] W. Ke, T.M. Svartaas, H.K. Abay, Effects of low concentration methanol, PVP and PVCap on structure-I methane hydrate formation, J. Energy Power Eng. 7(2013) 432-439.
[81] W. Ke, T.M. Svartaas, Effects of stirring and cooling on methane hydrate formation in a high pressure isochoric cell, J. Mater. Sci. Eng. B 3(7) (2013) 436-444.
[82] W. Ke, T.M. Svartaas, The effect of molar liquid water-gas ratio on methane hydrate formation, J. Mater. Sci. Eng. B 3(8) (2013) 510-517.
[83] H.K. Abay, T.M. Svartaas, W. Ke, Effect of gas composition on sII hydrate growth kinetics, Energy Fuel 25(2011) 1335-1341.
[84] J. Ivall, J. Pasieka, D. Posteraro, P. Servio, Profiling the concentration of the kinetic inhibitor Polyvinylpyrrolidone throughout the methane hydrate formation process, Energy Fuel 29(2015) 2329-2335.
[85] H. Sharifi, J.A. Ripmeester, V.K. Walker, P. Englezos, Kinetic inhibition of natural gas hydrates in saline solutions and heptane, Fuel 117(2014) 109-117.
[86] Y.V. Rojas González, Tetrahydrofuran and natural gas hydrates formation in the presence of various inhibitors, PhD. Thesis, Curtin University of Technology, Australia, 2011.
[87] H. Ohno, T.A. Strobel, S.F. Dec, E.D. Sloan, C.A. Koh, Raman studies of methane-ethane hydrate Metastability, J. Phys. Chem. A 113(9) (2009) 1711-1716.
[88] B.J. Anderson, J.W. Tester, G.P. Borghi, B.L. Trout, Properties of inhibitors of methane hydrate formation via molecular dynamics simulations, J. Am. Chem. Soc. 127(2005) 17852-17862.
[89] B. Kvamme, R. Åsnes, Mechanisms for kinetic hydrate inhibitors, Proceedings of the 4th WSEAS International Conference on Heat and Mass Transfer, Gold Coast, Queensland, Australia, 2007.
[90] D.A. Gómez Gualdrón, S. Aparicio-Martínez, P.B. Balbuena, Computational studies of structure and dynamics of clathrate inhibitor monomers in solution, Ind. Eng. Chem. Res. 46(1) (2007) 131-142.
[91] J.-H. Sa, G.-H. Kwak, K. Han, D. Ahn, K.-H. Lee, Gas hydrate inhibition by perturbation of liquid water structure, Sci. Rep. 5(2015), 11526.
[92] M.A. Kelland, E. Abrahamsen, H. Ajiro, M. Akashi, Kinetic hydrate inhibition with N-alkyl-N-vinylformamide polymers:Comparison of polymers to n-propyl and isopropyl groups, Energy Fuel 29(2015) 4941-4946.
[93] S. Park, H. Ro, J.-W. Lee, H. Kang, H. Lee, Morpholine-induced thermodynamic and kinetic inhibitions on gas hydrate formation, Energy Fuel 27(11) (2013) 6581-6586.
[94] L.D. Villano, M.A. Kelland, G.M. Miyake, E.Y.-X. Chen, Effect of polymer tacticity on the performance of poly(N,N-dialkylacrylamide)s as kinetic hydrate inhibitors, Energy Fuel 24(2010) 2554-2562.
[95] M. Varma-Nair, C.A. Costello, K.S. Colle, H.E. King, Thermal analysis of polymer-water interactions and their relation to gas hydrate inhibition, J. Appl. Polym. Sci. 103(2007) 2642-2653.
[96] B. Kvamme, T. Kuznetsova, K. Aasoldsen, Molecular dynamics simulations for selection of kinetic hydrate inhibitors, J. Mol. Graph. Model. 23(6) (2005) 524-536.
[97] R.W. Hawtin, P.M. Rodger, Polydispersity in oligomeric low dosage gas hydrate inhibitors, J. Mater. Chem. 16(20) (2006) 1934-1942.
[98] Z. Li, F. Jiang, H.B. Qin, B. Liu, C.Y. Sun, G.J. Chen, Molecular dynamics method to simulate the process of hydrate growth in the presence/absence of KHIs, Chem. Eng. Sci. 164(2017) 307-312.
[99] X. Zhao, Z. Qiu, W. Huang, Characterization of kinetics of hydrate formation in the presence of kinetic hydrate inhibitors during Deepwater drilling, J. Nat. Gas Sci. Eng. 22(2015) 270-278.
[100] P. Glénat, P. Bourg, M.-L. Bousqué, Selection of commercial kinetic hydrate inhibitors using a new crystal growth inhibition approach highlighting major differences between them, Proceedings of the SPE Middle East Oil and Gas Show and Conference (MEOS), Manama, Bahrain, 2013.
[101] K. McNamee, Evaluation of hydrate nucleation trends and kinetic hydrate inhibitor performance by high-pressure differential scanning calorimetry, Proceedings of the 7th International Conference on Gas Hydrates, Edinburgh, Scotland, United Kingdom, 2011.
[102] Y. Xu, M. Yang, X. Yang, Chitosan as green kinetic inhibitors for gas hydrate formation, J. Nat. Gas Chem. 19(4) (2010) 431-435.
[103] M.R. Talaghat, Intensification of the performance of kinetic inhibitors in the presence of polyethylene oxide and polypropylene oxide for simple gas hydrate formation in a flow mini-loop apparatus, Fluid Phase Equilib. 289(2010) 129-134.
[104] R. Anderson, H. Mozaffar, B. Tohidi, Development of a crystal growth inhibition based method for the evaluation of kinetic hydrate inhibitors, Proceedings of the 7th International Conference on Gas Hydrates, Edinburgh, Scotland, United Kingdom, 2011.
[105] U.C. Klomp, V. Kruka, R. Reinjhart, Low dosage inhibitors:(How) do they work, 2nd International Conference on Controlling Hydrates, Waxes and Asphaltenes, Aberdeen, Oct, 1997.
[106] T.Y. Makogon, R. Larsen, C.A. Knight, E.D. Sloan, Melt growth of tetrahydrofuran clathrate hydrate and its inhibition:Method and first results, J. Cryst. Growth 179(5) (1997) 258-262.
[107] R. Larsen, C.A. Knight, K.T. Rider, E.D. Sloan, Growth and inhibition of ethylene oxide clathrate hydrate, in:G.D. Holder, P.R. Bishnoi (Eds.), Gas Hydrates:Challenges for the Future, vol. 912, New York Academy of Sciences, New York 2000, pp. 441-451.
[108] T.M. Svartaas, A.C. Gulbrandsen, S.B.R. Huseboe, O. Sandved, An experimental study on "un-normal" dissociation properties of structure II hydrates formed in presence of PVCap in the region 30 to 175 bars-dissociation by temperature increase, Proceedings of the 6th International Conference on Gas Hydrates, Vancouver, Canada, 2008.
[109] S. Shahnazar, S. Bagheri, A. TermehYousefi, J. Mehrmashhadi, M.S.A. Karim, N.A. Kadri, Structure, mechanism, and performance evaluation of natural gas hydrate kinetic inhibitors, Rev. Inorg. Chem. (2018) 1-19.
[110] M.F. Mady, M.A. Kelland, Tris (tert-heptyl)-N-alkyl-1-ammonium bromides-powerful THF hydrate crystal growth inhibitors and their synergism with poly-Vinylcaprolactam kinetic gas hydrate inhibitor, Chem. Eng. Sci. 144(2016) 275-282.
[111] M.F. Mady, M.A. Kelland, Synergism of tert-heptylated quaternary ammonium salts with poly(nvinyl caprolactam) kinetic hydrate inhibitor in high-pressure and oilbased systems, Energy Fuel 32(2018) 4841-4849.
[112] P.C. Chua, M.A. Kelland, Tetra(iso-hexyl)ammonium bromide-the Most powerful quaternary ammonium-based tetrahydrofuran crystal growth inhibitor and synergist with Polyvinylcaprolactam kinetic gas hydrate inhibitor, Energy Fuel 26(2012) 1160-1168.
[113] H. Sefidroodi, P.C. Chua, M.A. Kelland, THF hydrate crystal growth inhibition with small anionic organic compounds and their synergistic properties with the kinetic hydrate inhibitor poly (N-vinylcaprolactam), Chem. Eng. Sci. 66(10) (2011) 2050-2056.
[114] M.F. Mady, M.A. Kelland, Fluorinated quaternary ammonium bromides:Studies on their tetrahydrofuran hydrate crystal growth inhibition and as synergists with polyvinylcaprolactam kinetic gas hydrate inhibitor, Energy Fuel (2013) 27.
[115] C. Nakarit, M.A. Kelland, D. Liu, E.Y.X. Chen, Cationic kinetic hydrate inhibitors and the effect on performance of incorporating cationic monomers into N-vinyl lactam copolymers, Chem. Eng. Sci. 102(2013) 424-431.
[116] C.D. Magnusson, M.A. Kelland, Study on the synergistic properties of quaternary phosphonium bromide salts with N-vinylcaprolactam based kinetic hydrate inhibitor polymers, Energy Fuel 28(2014) 6803-6810.
[117] W. Lee, J.-Y. Shin, K.-S. Kim, S.-P. Kang, Synergetic effect of ionic liquids on the kinetic inhibition performance of poly(Nvinylcaprolactam) for natural gas hydrate formation, Energy Fuel 30(2016) 9162-9169.
[118] W. Lee, K.-S. Kim, S.-P. Kang, J.-N. Kim, Synergetic performance of the mixture of poly(Nvinylcaprolactam) and a Pyrrolidinium-based ionic liquid for kinetic hydrate inhibition in the presence of the mineral oil phase, Energy Fuel 32(2018) 4932-4941.
[119] M.A. Kelland, N. Moi, M. Howarth, Breakthrough in synergists for kinetic hydrate inhibitor polymers, Hexaalkylguanidinium salts:Tetrahydrofuran hydrate crystal growth inhibition and synergism with Polyvinylcaprolactam, Energy Fuel 27(2) (2013) 711-716.
[120] F.T. Reyes, M.A. Kelland, Investigation of the kinetic hydrate inhibitor performance of a series of copolymers of N-vinyl Azacyclooctanone on structure II gas hydrate, Energy Fuel 27(2013) 1314-1320.
[121] A. Perrin, M.J. Goodwin, S. Callear, A.K. Soper, O.M. Musa, J.W. Steed, Structures of a clathrate hydrate former, inhibitor, and synergist in water, J. Phys. Chem. B 122(2018) 4901-4912.
[122] J. Yang, B. Tohidi, Characterization of inhibition mechanisms of kinetic hydrate inhibitors using ultrasonic test technique, Chem. Eng. Sci. 66(2011) 278-283.
[123] C. Tang, X. Dai, J. Du, D. Li, X. Zang, X. Yang, D. Liang, Kinetic studies of gas hydrate formation with low-dosage hydrate inhibitors, Sci. China Chem. 53(12) (2010) 2622-2627.
[124] A.C. Gulbrandsen, T.M. Svartaas, Influence of A Synergist on The Dissociation of Hydrates Formed in The Presence of The Kinetic Inhibitor Poly Vinyl Caprolactam, ICGH-6, Vancouver, Canada, 2008.
[125] Q. Zhang, R. Kawatani, H. Ajiro, M.A. Kelland, Optimizing the kinetic hydrate inhibition performance of NAlkylNvinylamide copolymers, Energy Fuel 32(2018) 4925-4931.
[126] M. Kim, Y.W. Bae, B. Lee, I.W. Cheong, W. Shin, LCST-modulated polymers for synergistic hydrate inhibition in methane gas flowlines, Energy Fuel 32(2018) 3013-3021.
[127] B. Tohidi, R. Anderson, H. Mozaffar, F. Tohidi, The return of kinetic hydrate inhibitors, Energy Fuel 29(12) (2015) 8254-8260.
[128] H.-B. Qin, C.-Y. Sun, Z.-F. Sun, B. Liu, G.-J. Chen, Relationship between the interfacial tension and inhibition performance of hydrate inhibitors, Chem. Eng. Sci. 148(2016) 182-189.
[129] L.T. Chen, C.Y. Sun, B.Z. Peng, G.J. Chen, The synergism of PEG to kinetic hydrate inhibitor, Proceedings of the 20th International Offshore and Polar Engineering Conference, International Society of Offshore and Polar Engineers, Beijing, China, 2010.
[130] N. Daraboina, C. Malmos, N. Von Solms, Investigation of kinetic hydrate inhibition using a high pressure micro differential scanning calorimeter, Energy Fuel 27(2013) 5779-5786.
[131] N. Daraboina, C. Malmos, N. Von Solms, Synergistic kinetic inhibition of natural gas hydrate formation, Fuel 108(2013) 749-757.
[132] J.D. Lee, P. Englezos, Unusual kinetic inhibition effects on gas hydrate formation, Chem. Eng. Sci. 61(2006) 1368-1376.
[133] J.D. Lee, P. Englezos, Enhancement of the performance of gas hydrate kinetic inhibitors with polyethylene oxide, Chem. Eng. Sci. 60(19) (2005) 5323-5330.
[134] M.R. Talaghat, Enhancement of the performance of kinetic inhibitors in the presence of polyethylene oxide and polypropylene oxide for binary mixtures during gas hydrate formation in a flow mini-loop apparatus, Can. J. Chem. Eng. 90(2012) 79-86.
[135] M.R. Talaghat, Enhancement of the performance of modified starch as a kinetic hydrate inhibitor in the presence of polyoxides for simple gas hydrate formation in a flow mini-loop apparatus, J. Nat. Gas Sci. Eng. 18(2014) 7-12.
[136] J.A. Garcia Chui, F. Ning, X. Wu, C. Sun, The effect of lecithin and PVP on gas hydrate formation in water-based drilling fluids for deep-water drilling, Proceedings of the 8th International Conference on Gas Hydrates, Beijing, China, 2014.
[137] X. Zhao, Z. Qiu, G. Zhou, W. Huang, Synergism of thermodynamic hydrate inhibitors on the performance of poly (vinyl Pyrrolidone) in Deepwater drilling fluid, J. Nat. Gas Sci. Eng. 23(2015) 47-54.