IntroductionIn the supercritical fluid state, the solvent properties (such as density, viscosity, and dielectric) are highly sensitive to small changes in pressure or temperature, especially in the immediate vicinity of the critical point. These "tunable" properties make supercritical fluid (SCF) solvents attractive for both separation (McHugh and Krukonis, 1986) and reaction processes (Wu et al., 1991). Commercially successful processes have been developed for SCF extraction. Applications of SCF solvents in reaction processes, however, are only beginning to emerge, and there are not many data available on reactions. Design and control of systems for reactions under supercritical conditions will require not only the same pure-component and mixture thermophysical properties needed for extractions (such as equations of state and mixing rules), but also additional mechanistic information on SCF solvent effects on reactions.Several studies of reactions revealed large solvent effects on the rate constants which have been explained in terms of "cage effects" or "clustering" of the solvent about solute molecules Johnston and Haynes, 1987;Wu et al., 1991;Combes et al., 1992). Solvatochromic (Yonker and Smith, 1988;Kim and Johnston, 1987;Johnston et al., 1989) and fluorescence spectroscopy (Brennecke and Eckert, 1989;Brennecke et al., 1990a;Betts et al., 1992) experiments among others have shown solute-solvent interactions higher than those in homogeneous liquids, leading to the conclusion that effective local solvent or cosolvent densities can be several times higher than the bulk densities. Reaction rates are affected simultaneously through both the rate constants and the local concentrations of the reactants. Because these effects may exhibit opposite pressure dependencies, understanding of the phenomena involved at the molecular level can greatly improve the choice of physical conditions and prediction of reaction rates, and allow the tailoring of SCF solutions for specific applications. Despite the experimental and computational evidence for their existence, solvent-solute clusters have been the subject of a recent debate (Economou and Donohue, 1990;Brennecke et al., 1990b pressibilities result from long-range effects, while local density measurements by various spectroscopic techniques reflect shortrange order. The two types of effects may not necessarily be coincident; we will show data from two systems which suggest the contrary.
