0000000000465614

AUTHOR

Ludwik Leibler

showing 3 related works from this author

Gas Transport in Interacting Planar Brushes

2021

Recent experiments on melts of spherical nanoparticles (NPs) densely grafted with polymer chains show enhanced gas transport relative to the neat polymer (without NPs). As a means of understanding this unexpected behavior, we consider here the simpler case of two interacting planar brushes, under conditions representing a polymer melt far below its critical point (i.e., where the "free volume" or holes act akin to a poor solvent). Computer simulations illustrate, in agreement with mean-field ideas, that the density profile far away from the walls is flat but with a value that is marginally larger than the corresponding polymer melt under identical state conditions. We find that tracer parti…

TP1080-1185Materials sciencePlanarChemical physicsPolymers and polymer manufactureGeneral MedicineArticle
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Order-disorder-and order-order-transitions in AB and ABC block copolymers: description by a simple model

1996

Based on the description of AB-block copolymers as micellar structures given by Semenov, the phase diagram of AB-diblock copolymers is calculated taking the homogeneously mixed system as a reference state. The predicted value (χN)c = 10.385 for a symmetric AB-diblock copolymer compares very well to the result of the original Random Phase Approximation theory (10.495). The simplicity of the model allows its extension to predict order-order transitions in ABC-triblock copolymers.

SpinodalMaterials sciencePolymers and PlasticsValue (computer science)ThermodynamicsGeneral ChemistryState (functional analysis)Condensed Matter PhysicsSimple (abstract algebra)Materials ChemistryCopolymerOrder (group theory)Random phase approximationPhase diagramPolymer Bulletin
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Tuning Selectivities in Gas Separation Membranes Based on Polymer-Grafted Nanoparticles

2020

Polymer membranes are critical to many sustainability applications that require the size-based separation of gas mixtures. Despite their ubiquity, there is a continuing need to selectively affect the transport of different mixture components while enhancing mechanical strength and hindering aging. Polymer-grafted nanoparticles (GNPs) have recently been explored in the context of gas separations. Membranes made from pure GNPs have higher gas permeability and lower selectivity relative to the neat polymer because they have increased mean free volume. Going beyond this ability to manipulate the mean free volume by grafting chains to a nanoparticle, the conceptual advance of the present work is…

Materials scienceheterogeneous transport mediaimproved selective transportSynthetic membraneGeneral Physics and AstronomyNanoparticlegas separation membraneContext (language use)02 engineering and technology010402 general chemistry01 natural sciencesGeneral Materials ScienceGas separationfree volume distributionchemistry.chemical_classificationpolymer-grafted nanoparticlesGeneral EngineeringPolymer021001 nanoscience & nanotechnology0104 chemical sciencesMembranechemistryChemical engineeringVolume (thermodynamics)mixed matrix membrane0210 nano-technologySelectivity
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