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3 Dilute Solution Thermodynamics, Molecular Weights, and Sizes 71 3.1 Introduction / 71 3.2 The Solubility Parameter / 73 3.3 Thermodynamics of Mixing / 79 3.4 Molecular Weight Averages / 85 3.5 Determination of the Number-Average Molecular Weight / 87
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3 Dilute Solution Thermodynamics, Molecular Weights, and Sizes 71 3.1 Introduction / 71 3.2 The Solubility Parameter / 73 3.3 Thermodynamics of Mixing / 79 3.4 Molecular Weight Averages / 85 3.5 Determination of the Number-Average Molecular Weight / 87 3.6 Weight-Average Molecular Weights and Radii of Gyration / 91 3.7 Molecular Weights of Polymers / 103 3.8 Intrinsic Viscosity / 110 3.9 Gel Permeation Chromatography / 117 3.10 Mass Spectrometry / 130 3.11 Instrumentation for Molecular Weight Determination / 134 3.12 Solution Thermodynamics and Molecular Weights / 135 4 Concentrated Solutions, Phase Separation Behavior, and Diffusion 145 4.1 Phase Separation and Fractionation / 145 4.2 Regions of the Polymer–Solvent Phase Diagram / 150 4.3 Polymer–Polymer Phase Separation / 153 4.4 Diffusion and Permeability in Polymers / 172 4.5 Latexes and Suspensions / 184 4.6 Multicomponent and Multiphase Materials / 186 References /
Solubility parameter Regular solutions – heat of mixing (Hilderbrand and Scott 1949) V is total volume, DE is energy of vaporization, f volume fraction Before mixing After mixing If we assume that there is no specific interactions (hydrogen bonding etc.) , we ca assume that interaction e12 is some average from e11 and e22 Example geometrical mean (small numbers are more weighted) e11 represents how molecules 1 interact with itself – i.e. Cohesive energy or energy of vaporization energy of vaporization per volume
General rule: polymer will dissolve if solubility parameters (solvent and polymer) are close to each other (1) If there are specific interactions (like hydrogen bonding...) then polymer can dissolve even if the solubility parameter difference is large.. Like poly(ethylene oxide) and water..
3.2.2 Experimental determination Crosslinked polymers: Best solvent gives the maximum swelling Non-crosslinked polymers: Best solvent (best solvent = similar solubility parameter) – polymer coil conformation is most expanded instric viscosity largest
Theoretical calculation ,where G is group molar attraction constant, r polymer density and M is repeat unit molar mass Example polystyrene: 133 28 735 Example polyethylene:
Phase diagrams Small molecule mixtures:
Special case – symmetric composition: Binodal – coexistence curve