Search results for "Capillary condensation"

showing 8 items of 18 documents

Organic solvents vapor pressure and relative humidity effects on the phase transition rate of α and β forms of tegafur.

2011

The objective of this work was to investigate the relative humidity (RH) and solvent vapor pressure effects on the phase transition dynamics between tegafur polymorphic forms that do not form hydrates and solvates. The commercially available α and β modifications of 5-fluoro-1-(tetrahydro-2-furyl)-uracil, known as the antitumor agent tegafur, were used as model materials for this study. While investigating the phase transitions of α and β tegafur under various partial pressures of methanol, n-propanol, n-butanol, and water vapor, it was determined that the phase transition rate increased in the presence of solvent vapors, even though no solvates were formed. By increasing the relative air h…

Phase transitionAntimetabolites AntineoplasticChromatographyCapillary condensationVapor PressureChemistryVapor pressureMethanolAnalytical chemistryPharmaceutical ScienceWaterHumidityGeneral MedicinePartial pressure1-PropanolPhase TransitionReaction rate constant1-ButanolPhase (matter)Relative humidityCrystallizationWater vaporTegafurPharmaceutical development and technology
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From capillary condensation to interface localization transitions in colloid-polymer mixtures confined in thin-film geometry.

2008

Monte Carlo simulations of the Asakura-Oosawa (AO) model for colloid-polymer mixtures confined between two parallel repulsive structureless walls are presented and analyzed in the light of current theories on capillary condensation and interface localization transitions. Choosing a polymer to colloid size ratio of q=0.8 and studying ultrathin films in the range of D=3 to D=10 colloid diameters thickness, grand canonical Monte Carlo methods are used; phase transitions are analyzed via finite size scaling, as in previous work on bulk systems and under confinement between identical types of walls. Unlike the latter work, inequivalent walls are used here: while the left wall has a hard-core rep…

Phase transitionCapillary waveMonte Carlo methodFOS: Physical sciencesMonte-Carlo simulationCondensed Matter - Soft Condensed Mattercomplex mixtures01 natural sciences010305 fluids & plasmasColloiddemixing transition in confinement0103 physical sciences010306 general physicsScalingPhysicsCondensed Matter - Materials ScienceCondensed matter physicsCapillary condensationdigestive oral and skin physiologyMaterials Science (cond-mat.mtrl-sci)3. Good healthUniversality (dynamical systems)Condensed Matter::Soft Condensed Mattercolloid-polymer mixturesSoft Condensed Matter (cond-mat.soft)Ising modelPhysical review. E, Statistical, nonlinear, and soft matter physics
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Confinement effects on phase behavior of soft matter systems.

2008

When systems that can undergo phase separation between two coexisting phases in the bulk are confined in thin film geometry between parallel walls, the phase behavior can be profoundly modified. These phenomena shall be described and exemplified by computer simulations of the Asakura-Oosawa model for colloid-polymer mixtures, but applications to other soft matter systems (e.g. confined polymer blends) will also be mentioned. Typically a wall will prefer one of the phases, and hence the composition of the system in the direction perpendicular to the walls will not be homogeneous. If both walls are of the same kind, this effect leads to a distortion of the phase diagram of the system in thin …

Phase transitionMaterials scienceFOS: Physical sciences02 engineering and technologySoft modesCondensed Matter - Soft Condensed Matter01 natural sciencesPhysics::Fluid DynamicsLiquid crystalPhase (matter)0103 physical sciencesLamellar structureSoft matter010306 general physicsMonte Carlo simulationphase behavior in confinementPhase diagramCondensed Matter - Materials ScienceChromatographyCondensed matter physicsCapillary condensationMaterials Science (cond-mat.mtrl-sci)colloidal systemsGeneral Chemistry021001 nanoscience & nanotechnologyCondensed Matter PhysicsCondensed Matter::Soft Condensed MatterSoft Condensed Matter (cond-mat.soft)0210 nano-technologySoft matter
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Capillary condensation in cylindrical pores: Monte Carlo study of the interplay of surface and finite size effects.

2010

When a fluid that undergoes a vapor to liquid transition in the bulk is confined to a long cylindrical pore, the phase transition is shifted (mostly due to surface effects at the walls of the pore) and rounded (due to finite size effects). The nature of the phase coexistence at the transition depends on the length of the pore: For very long pores the system is axially homogeneous at low temperatures. At the chemical potential where the transition takes place fluctuations occur between vapor-like and liquid-like states of the cylinder as a whole. At somewhat higher temperatures (but still far below bulk criticality) the system at phase coexistence is in an axially inhomogeneous multi-domain …

Phase transitionMaterials scienceStatistical Mechanics (cond-mat.stat-mech)Condensed matter physicsCapillary condensationMonte Carlo methodFOS: Physical sciencesGeneral Physics and AstronomyAdsorptionLattice (order)CylinderIsing modelPhysical and Theoretical ChemistryAxial symmetryCondensed Matter - Statistical MechanicsThe Journal of chemical physics
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Polymer mixtures in confined geometries: Model systems to explore phase transitions

2005

While binary (A,B) symmetric polymer mixtures ind = 3 dimensions have an unmixing critical point that belongs to the 3d Ising universality class and crosses over to mean field behavior for very long chains, the critical behavior of mixtures confined into thin film geometry falls in the 2d Ising class irrespective of chain length. The critical temperature always scales linearly with chain length, except for strictly two-dimensional chains confined to a plane, for whichT; c ∝N; 5/8 (this unusual exponent describes the fractal contact line between segregated chains in dense melts in two spatial dimensions, d = 2). When the walls of the thin film are not neutral, but preferentially attract one …

Phase transitionwettingMaterials scienceCondensed matter physicsCapillary condensationPolymersGeneral Physics and AstronomyQuímicaRenormalization groupfinite size scalingMean field theoryCritical point (thermodynamics)ExponentIsing modelphase separationMonte Carlo simulationPhase diagram
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Rounding of Phase Transitions in Cylindrical Pores

2010

Phase transitions of systems confined in long cylindrical pores (capillary condensation, wetting, crystallization, etc.) are intrinsically not sharply defined but rounded. The finite size of the cross section causes destruction of long range order along the pore axis by spontaneous nucleation of domain walls. This rounding is analyzed for two models (Ising/lattice gas and Asakura-Oosawa model for colloid-polymer mixtures) by Monte Carlo simulations and interpreted by a phenomenological theory. We show that characteristic differences between the behavior of pores of finite length and infinitely long pores occur. In pores of finite length a rounded transition occurs first, from phase coexiste…

PhysicsPhase transitionStatistical Mechanics (cond-mat.stat-mech)Condensed matter physicsCapillary condensationMonte Carlo methodFOS: Physical sciencesGeneral Physics and Astronomylaw.inventionCondensed Matter::Soft Condensed MatterlawLattice (order)Ising modelWettingCrystallizationAxial symmetryCondensed Matter - Statistical Mechanics
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Wetting in fluid systems. Wetting and capillary condensation of lattice gases in thin film geometry

1994

Monte Carlo studies of lattice gas models with attractive interactions between nearest neighbors on a simple cubic lattice are carried out for a L×L×D geometry with two hard walls of size L×L and periodic boundary conditions parallel to the wall. Two types of short-range forces at the walls are considered: (i) Both walls are of the same type and exert an attractive force of the same strength (in Ising model terminology, surface fields HD = H1 occur). (ii) The walls differ, one attracts and the other repels particles, again with the same strength (HD = −H1). In the first case, capillary condensation occurs at a chemical potential differing from its value for phase coexistence in the bulk, an…

Physics::Fluid DynamicsCondensed matter physicsCapillary condensationWetting transitionChemistryGeneral Chemical EngineeringLattice (order)Critical phenomenaPeriodic boundary conditionsIsing modelGeometryStatistical mechanicsWettingBerichte der Bunsengesellschaft für physikalische Chemie
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Rotational State Change of Acetonitrile Vapor on MCM-41 upon Capillary Condensation with the aid of Time-Correlation Function Analysis of IR Spectros…

2000

The infrared spectra of adsorbed acetonitrile on MCM-41 (porewidth = 3.2 nm) were measured at 303 K. In the CN stretching ν2 region, two bands were observed at 2265 cm− 1 and 2254 cm− 1, assigned to hydrogen-bonded molecules on surface hydroxyls of MCM-41, and physisorbed molecules in mesopores, respectively. We designate here the 2265 cm− 1 band as the ν2α band and the 2254 cm− 1 band as the ν2β band. The bandwidth of the fundamental transition ν2fβ, was obtained by removing the overlap with hot band transitions of the same mode, ν2α band, and other modes by least-squares fitting. Before capillary condensation, the relaxation time τ obtained from the bandwidth of the ν2fβ band was smaller …

chemistry.chemical_compoundAdsorptionCapillary condensationMCM-41chemistryAnalytical chemistryInfrared spectroscopyMoleculeMesoporous materialAcetonitrileHot band
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