1998
DOI: 10.1103/physrevlett.81.1326
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Universal Law of Fractionation for Slightly Polydisperse Systems

Abstract: By perturbing about a general monodisperse system, we provide a complete description of twophase equilibria in any system which is slightly polydisperse in some property (e.g. particle size, charge, etc.). We derive a universal law of fractionation which is corroborated by comprehensive experiments on a model colloid-polymer mixture. We furthermore predict that phase separation is an e ective method of reducing polydispersity only for systems with a skewed distribution of the polydisperse property.PACS numbers… Show more

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Cited by 77 publications
(120 citation statements)
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“…And, where such inhomogeneous situations have been studied [9] it has often proved necessary to assume that only the mean density, and not the size distribution, can vary in space [10]. This ignores size segregation effects, which (globally) influence the phase diagram [3,7]. A similar tendency to local segregation is implicit in treatments of binary and ternary hard sphere mixtures [11][12][13] and in polydisperse equilibrium structure factors in the homogeneous state [4].…”
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confidence: 99%
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“…And, where such inhomogeneous situations have been studied [9] it has often proved necessary to assume that only the mean density, and not the size distribution, can vary in space [10]. This ignores size segregation effects, which (globally) influence the phase diagram [3,7]. A similar tendency to local segregation is implicit in treatments of binary and ternary hard sphere mixtures [11][12][13] and in polydisperse equilibrium structure factors in the homogeneous state [4].…”
mentioning
confidence: 99%
“…The fact that all colloids are in practice polydisperse (at least slightly) must then be taken into account in comparing theory with experiment. Only recently has experimental work started to clarify in a systematic way the generic consequences of polydispersity, such as the partitioning of sizes between coexisting phases [3].Despite the continuous interest polydisperse fluids have raised, their theoretical understanding remains far from complete, especially for inhomogeneous cases. More is known about partial structure factors in single-phase fluids [4,5] and liquid-liquid phase equilibrium [6,7] than about crystalline phases [8] or interfacial properties, for example.…”
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“…In many experimental or industrially relevant circumstances, the particular components (spheres) of a system are not uniform in size but rather display some distribution of sizes or "polydispersity" [164]. Interesting phenomena arise in the presence of a wide polydispersity [25,34,207], but due to the wide size distribution across many scales, it is difficult to provide simple accurate statistical models [208,209] for such systems. In many fluidbased theories, for example, Percus-Yevick integral equation theory [210,211], scaled-particle theory [55], Boublík, Mansoori, Carnahan, Starling, and Leland (BMCSL) equation of state (EOS) [57,58], Rosenfeld's fundamental measure theory [212], A. Santos' approaches [59][60][61], and others [49,52,213], it is assumed that the dependence of the polydisperse pressure of N hard spheres on the N degrees of freedom (volume fraction plus N − 1 size ratios) can be encapsulated into the dependence of only three parameters, i.e., the volume fraction and the second and third scaled moments (divided by the first moment, with appropriate power).…”
Section: Poly-versus Tri-disperse Systems †mentioning
confidence: 99%