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The Flory–Schulz distribution is a discrete probability distribution named after Paul Flory and Günter Victor Schulz that describes the relative ratios of polymers of different length that occur in an ideal step-growth polymerization process.
Paul John Flory (June 19, 1910 – September 9, 1985) was an American chemist and Nobel laureate who was known for his work in the field of polymers, or macromolecules. [2] He was a pioneer in understanding the behavior of polymers in solution, and won the Nobel Prize in Chemistry in 1974 "for his fundamental achievements, both theoretical and ...
Flory may refer to: Flory (surname) Flory Van Donck (1912-1992), Belgian golfer; Flory Cirque, a cirque (valley) in Victoria Land, Antarctica;
Reviews of the Spitfire and Mustang found little to fault with the kits. Model building reviewers have praised the kit of the Spitfires in particular for their fidelity of form, and near-completeness of execution. [31] The model's complexity and detail even gave rise to publications devoted explicitly to their construction and finishing. [32]
Monarch Models, now Monarch Model Company, is based in London, Ontario, Canada – started by a doctor. [26] [27] Atlantis Models is based in Deer Park, New York, and though also making sci-fi figures, has equal focus on animal dioramas. In 2018 Atlantis Purchased most of the Aurora Tooling that remained at Revell Monogram in Elk Grove.
Flory–Stockmayer theory is a theory governing the cross-linking and gelation of step-growth polymers. [1] The Flory–Stockmayer theory represents an advancement from the Carothers equation , allowing for the identification of the gel point for polymer synthesis not at stoichiometric balance. [ 1 ]
Mixture of polymers and solvent on a lattice. Flory–Huggins solution theory is a lattice model of the thermodynamics of polymer solutions which takes account of the great dissimilarity in molecular sizes in adapting the usual expression for the entropy of mixing.
The Flory–Fox equation relates the number-average molecular weight, M n, to the glass transition temperature, T g, as shown below: =, where T g,∞ is the maximum glass transition temperature that can be achieved at a theoretical infinite molecular weight and K is an empirical parameter that is related to the free volume present in the polymer sample.