Statistical associating fluid theory (SAFT) [1][2] is a chemical theory, based on perturbation theory, that uses statistical thermodynamics to explain how complex fluids and fluid mixtures form associations through hydrogen bonds.[3] Widely used in industry and academia, it has become a standard approach for describing complex mixtures.[4][5][6][7] Since it was first proposed in 1990, SAFT has been used in a large number of molecular-based equation of state[8][9] models for describing the Helmholtz energy contribution due to association.
SAFT evolved from thermodynamic theories, including perturbation theories developed in the 1960s, 1970s, and 1980s by John Barker and Douglas Henderson, Keith Gubbins and Chris Gray, and, in particular, Michael Wertheim's first-order, thermodynamic perturbation theory (TPT1) outlined in a series of papers in the 1980s.[2][11]
The SAFT equation of state was developed using statistical mechanical methods (in particular the perturbation theory of Wertheim[12]) to describe the interactions between molecules in a system.[1][13][14] The idea of a SAFT equation of state was first proposed by Walter G. Chapman and by Chapman et al. in 1988 and 1989.[1][13][14] Many different versions of the SAFT models have been proposed, but all use the same chain and association terms derived by Chapman et al.[2][13][15] One of the first SAFT papers (1990) titled "New reference equation of state for associating liquids" by Walter G. Chapman, Keith Gubbins, George Jackson, and Maciej Radosz,[2] was recognized in 2007 by Industrial and Engineering Chemistry Research as one of the most highly cited papers of the previous three decades.[16] SAFT is one of the first theories to accurately describe (in comparison with molecular simulation) the effects on fluid properties of molecular size and shape in addition to association between molecules.[1][2][13][14]
Many variations of SAFT have been developed since the 1990s, including HR-SAFT (Huang-Radosz SAFT),[6]PC-SAFT (perturbed chain SAFT),[17][18] Polar SAFT,[19] PCP-SAFT (PC-polar-SAFT),[20][21][22] soft-SAFT,[23] polar soft-SAFT,[24] SAFT-VR (variable range),[25] SAFT VR-Mie.[26] Also, the SAFT term was used in combination with cubic equations of state for describing the dispersive-repulsive interactions, for example in the Cubic-Plus-Association (CPA) equation of state model[27] and the SAFT + cubic model [28] and non-random-lattice (NLF) models based on lattice field theory.[3]
^ abcdefChapman, Walter G.; Gubbins, Keith E.; Jackson, George; Radosz, Maciej (August 1990). "New reference equation of state for associating liquids". Industrial & Engineering Chemistry Research. 29 (8): 1709–1721. doi:10.1021/IE00104A021. eISSN1520-5045. ISSN0888-5885.
^ abKontogeorgis, Georgios M.; Folas, Georgios K. (2010). "The Statistical Associating Fluid Theory (SAFT)". Thermodynamic Models for Industrial Applications. John Wiley & Sons, Ltd. pp. 221–259. doi:10.1002/9780470747537.ch8. ISBN9780470747537.
^ abEconomou, Ioannis G. (4 October 2001). "Statistical Associating Fluid Theory: A Successful Model for the Calculation of Thermodynamic and Phase Equilibrium Properties of Complex Fluid Mixtures". Industrial & Engineering Chemistry Research. 41 (5): 953–962. doi:10.1021/ie0102201. eISSN1520-5045. ISSN0888-5885.
^ abHuang, Stanley H.; Radosz, Maciej (November 1990). "Equation of state for small, large, polydisperse, and associating molecules". Industrial & Engineering Chemistry Research. 29 (11): 2284–2294. doi:10.1021/ie00107a014. eISSN1520-5045. ISSN0888-5885.
^ abcdChapman, Walter G. (1988). "Theory and Simulation of Associating Liquid Mixtures". Doctoral Dissertation, Cornell University.
^ abcChapman, Walter G.; Jackson, G.; Gubbins, K.E. (11 July 1988). "Phase equilibria of associating fluids: Chain molecules with multiple bonding sites". Molecular Physics. 65: 1057–1079. doi:10.1080/00268978800101601.
^Gil-Villegas, Alejandro; Galindo, Amparo; Whitehead, Paul J.; Mills, Stuart J.; Jackson, George; Burgess, Andrew N. (1997). "Statistical associating fluid theory for chain molecules with attractive potentials of variable range". The Journal of Chemical Physics. 106 (10): 4168–4186. Bibcode:1997JChPh.106.4168G. doi:10.1063/1.473101.
^Kontogeorgis, Georgios M.; Michelsen, Michael L.; Folas, Georgios K.; Derawi, Samer; von Solms, Nicolas; et al. (1 June 2006). "Ten Years with the CPA (Cubic-Plus-Association) Equation of State. Part 1. Pure Compounds and Self-Associating Systems". Industrial & Engineering Chemistry Research. 45 (14): 4855–4868. doi:10.1021/ie051305v. eISSN1520-5045. ISSN0888-5885.