Theory of Scattering by an Inhomogeneous Solid Possessing Fluctuations in Density and Anisotropy

Goldstein, Martin; Michalik, Ewa

doi:10.1063/1.1721930

Cited by 66 publications

(10 citation statements)

References 8 publications

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“…These values are in good agreement with p calculated for the king model by means of the renormalization group method (Wilson and Kogut, 1974;Raker et al, 1976;Golner and Riedel, 1976;Ma shang-keng, 1976; le Guillou and Zimm-Justin, 1977).…”

Section: 3supporting

confidence: 75%

“…Such fluctuations arise as a result of mutual orientation of anisotropic molecules, or of their aggregates, or owing to the internal stresses in solid matter. In this case, the polarizability of scattering elements is represented by a polarizability tensor and two corrclation functions (density correlation and orientation correlation) are introduced (Goldstein and Michalik, 1955;van Aartsen, 1972).…”

Section: Rr2z2 Z)mentioning

confidence: 99%

See 1 more Smart Citation

Thermodynamics of Systems Containing Flexible-Chain Polymers

Klenin¹,

Frenkelʹ²

1999

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Section: 3supporting

confidence: 75%

Section: Rr2z2 Z)mentioning

confidence: 99%

Thermodynamics of Systems Containing Flexible-Chain Polymers

Klenin¹,

Frenkelʹ²

1999

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“…2(c)]. For small scattering angles, the total scattering intensity is given by18, 39, 56, 57 In eq 6, ω η and ω δ are the correlation volumes for density and orientation fluctuations 18, 56, 57. For a two‐phase system of crystalline and amorphous polymer the mean‐square density (〈η

_{2}^{1}

〉) and orientation (〈δ

_{2}^{1}

〉) fluctuations are given by where the volume fraction crystallinity is ϕ c , the average crystalline polarizability is α c , and α a is the polarizability of the amorphous phase, assumed to be isotropic.…”

Section: Sals Modelmentioning

confidence: 99%

Multivariable structural characterization of semicrystalline polymer blends by small‐angle light scattering

Akpalu

Lin

2002

J Polym Sci B Polym Phys

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A new multi-variable-measurement approach for characterizing and correlating the nanoscale and microscale morphology of crystal-amorphous polymer blends with melt-phase behavior is described. A vertical small-angle light scattering (SALS) instrument optimized for examining the scattering and light transmitted from structures ranging from 0.5 to 50 m, thereby spanning the size range characteristic of the initial-to-late stages of thermal-phase transitions (e.g., melt-phase separation and crystallization) in crystal-amorphous polymer blends, was constructed. The SALS instrument was interfaced with differential scanning calorimetry (DSC), and simultaneous SALS/DSC/transmission measurements were performed. We show that the measurement of transmitted light and SALS under H V (cross-polarized) optical alignments during melting can be used to reliably measure the thermodynamic (e.g., crystal melting and melt-phase separation temperatures) and structural variables (e.g., crystalline fraction within the superstructures and volume fraction of superstructures) necessary for describing the multiphase behavior of crystal-amorphous blends in one combined measurement. We also evaluate the orientation correlations of crystalline volume elements within the superstructures. Our results indicate that simultaneous measurement of transmitted light can provide a reliable estimate of the total scattering from density and orientation fluctuations and the melt-phase separation temperature of polymer blends. For solution-cast poly(⑀-caprolactone)/poly(D,L-lactic acid) blends, our multivariable measurements during melting provide the parameters necessary to generate a crystal-liquid and liquid-liquid phase diagram and characterize the solidstate morphology. This opens up the challenge to explore use of our vertical SALS instrument as a rapid and convenient method for developing structure-property relationships for crystal-amorphous polymer blends.

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“…Light scattering by polymer chains in solution has much in common with light scattering by an isotropic, inhomogeneous solid. 3 Concerning the latter problem Goldstein and Michalik 4 developed a very general theory, whose result might be usable for the present purpose. Unfortunately they introduced some simplifying assumptions: the axial symmetry of polarizability of each unit and an assumption about the orientational distribution between two units which together spoil complete generality.…”

mentioning

confidence: 99%

Theory of Light Scattering by an Isotropic System Composed of Anisotropic Units with Application to the Porod–Kratky Chain

Nagai

1972

Polym J

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A theory of elastic (Rayleigh-Debye) light scattering by an isotropic system composed of anisotropic units is developed. Each unit is regarded optically as a point scatterer with three different principal polarizabilities. No assumption is introduced about the radial and orientational distributions for any pair of units. The only assumption is the random orientation of the system as a whole with respect to the light-scattering framework ("isotropic" system). Theory is formally adapted to infinitely dilute solutions of polymers of completely general structure. Detailed calculations are carried out for the Porod-Kratky wormlike chain. A method is suggested for determining the parameters of the Porod-Kratky chain through comparison of the theory with experimental data on polymer chains of moderate length. Chain-length dependences of various terms in expressions for reduced intensities are inferred for general chains from those for the Porod-Kratky chain. The correspondence of the Porod-Kratky chain with general chains is thereby discussed. A detailed comparison is also made of our results for the Porod-Kratky chain and general chains with those for the random chain reported by Utiyama and Kurata.

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Theory of Scattering by an Inhomogeneous Solid Possessing Fluctuations in Density and Anisotropy

Cited by 66 publications

References 8 publications

Thermodynamics of Systems Containing Flexible-Chain Polymers

Thermodynamics of Systems Containing Flexible-Chain Polymers

Multivariable structural characterization of semicrystalline polymer blends by small‐angle light scattering

Theory of Light Scattering by an Isotropic System Composed of Anisotropic Units with Application to the Porod–Kratky Chain

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