Search results for "Debye function"

showing 3 items of 3 documents

Scattering function of semiflexible polymer chains under good solvent conditions

2012

Using the pruned-enriched Rosenbluth Monte Carlo algorithm, the scattering functions of semiflexible macromolecules in dilute solution under good solvent conditions are estimated both in $d=2$ and $d=3$ dimensions, considering also the effect of stretching forces. Using self-avoiding walks of up to $N = 25600$ steps on the square and simple cubic lattices, variable chain stiffness is modeled by introducing an energy penalty $\epsilon_b$ for chain bending; varying $q_b=\exp (- \epsilon_b/k_BT)$ from $q_b=1$ (completely flexible chains) to $q_b = 0.005$, the persistence length can be varied over two orders of magnitude. For unstretched semiflexible chains we test the applicability of the Krat…

Persistence lengthPhysicsCharacteristic lengthScatteringGeneral Physics and AstronomyFOS: Physical sciencesCondensed Matter - Soft Condensed MatterSquare (algebra)Condensed Matter::Soft Condensed Mattersymbols.namesakeChain (algebraic topology)Quantum mechanicsKuhn lengthsymbolsSoft Condensed Matter (cond-mat.soft)Debye functionPhysical and Theoretical ChemistryMonte Carlo algorithm
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A real-space approach to the analysis of stacking faults in close-packed metals: G(r) modelling and Q-space feedback

2019

An R-space approach to the simulation and fitting of a structural model to the experimental pair distribution function is described, to investigate the structural disorder (distance distribution and stacking faults) in close-packed metals. This is carried out by transferring the Debye function analysis into R space and simulating the low-angle and high-angle truncation for the evaluation of the relevant Fourier transform. The strengths and weaknesses of the R-space approach with respect to the usual Q-space approach are discussed.

PhysicsTruncationMathematical analysisStackingPair distribution functionCondensed Matter PhysicsSpace (mathematics)BiochemistryInorganic Chemistrysymbols.namesakeFourier transformDistribution (mathematics)Structural BiologysymbolsGeneral Materials ScienceDebye functionPhysical and Theoretical ChemistryActa Crystallographica Section A Foundations and Advances
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A real-space approach to the analysis of stacking faults in close-packed metals: Modelling and Q-space feedback Longo Alessandro

2020

An R-space approach to the simulation and fitting of a structural model to the experimental pair distribution function is described, to investigate the structural disorder (distance distribution and stacking faults) in close-packed metals. This is carried out by transferring the Debye function analysis into R space and simulating the low-angle and high-angle truncation for the evaluation of the relevant Fourier transform. The strengths and weaknesses of the R-space approach with respect to the usual Q-space approach are discussed.

close-packed metalstacking faultcobalt.pair distribution functioncobaltDebye function analysi
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