Search results for "SURFACE-TENSION"

showing 3 items of 3 documents

Monte Carlo simulations of the solid-liquid transition in hard spheres and colloid-polymer mixtures

2010

Monte Carlo simulations at constant pressure are performed to study coexistence and interfacial properties of the liquid-solid transition in hard spheres and in colloid-polymer mixtures. The latter system is described as a one-component Asakura-Oosawa (AO) model where the polymer's degrees of freedom are incorporated via an attractive part in the effective potential for the colloid-colloid interactions. For the considered AO model, the polymer reservoir packing fraction is eta_p^r=0.1 and the colloid-polymer size ratio is q=sigma_p/\sigma=0.15 (with sigma_p and sigma the diameter of polymers and colloids, respectively). Inhomogeneous solid-liquid systems are prepared by placing the solid fc…

ANISOTROPIC SURFACE-TENSIONMaterials scienceMonte Carlo methodDegrees of freedom (physics and chemistry)General Physics and AstronomyThermodynamicsCondensed Matter - Soft Condensed MatterCAPILLARY WAVESAtomic packing factorCOMPUTER-SIMULATIONVAPOR INTERFACE3-DIMENSIONAL ISING-MODELColloidsymbols.namesakePhase (matter)Physical and Theoretical ChemistryCOEXISTING PHASESchemistry.chemical_classificationCondensed Matter - Materials ScienceINTERFACIAL FREE-ENERGYPROFILESHard spheresPolymerCondensed Matter::Soft Condensed MatterchemistryCRYSTAL-MELT INTERFACESBoltzmann constantsymbolsCRYSTALLIZATIONThe Journal of Chemical Physics
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Interfacial water structure controls protein conformation.

2007

A phenomenological theory of salt-induced Hofmeister phenomena is presented, based on a relation between protein solubility in salt solutions and protein-water interfacial tension. As a generalization of previous treatments, it implies that both kosmotropic salting out and chaotropic salting in are manifested via salt-induced changes of the hydrophobic/hydrophilic properties of protein-water interfaces. The theory is applied to describe the salt-dependent free energy profiles of proteins as a function of their water-exposed surface area. On this basis, three classes of protein conformations have been distinguished, and their existence experimentally demonstrated using the examples of bacter…

DYNAMICSMECHANISMKosmotropicProtein ConformationSURFACE-TENSIONSurface tensionchemistry.chemical_compoundProtein structureMaterials ChemistryPhysical and Theoretical ChemistryPURPLE MEMBRANESPECTROSCOPYbiologySTABILITYBACTERIORHODOPSINMyoglobinSALTTemperatureWaterBacteriorhodopsinSTABILITY MECHANISMSurfaces Coatings and FilmsION SPECIFICITYChaotropic agentCrystallographyMyoglobinchemistryTEMPERATURE-DEPENDENCEChemical physicsStructural stabilityBacteriorhodopsinsbiology.proteinSalting outThermodynamicsThe journal of physical chemistry. B
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Evidence for the Existence of an Effective Interfacial Tension between Miscible Fluids: Isobutyric Acid-Water and 1-Butanol-Water in a Spinning-Drop …

2006

We report definitive evidence for an effective interfacial tension between two types of miscible fluids using spinning-drop tensiometry (SDT). Isobutyric acid (IBA) and water have an upper critical solution temperature (UCST) of 26.3 degrees C. We created a drop of the IBA-rich phase in the water-rich phase below the UCST and then increased the temperature above it. Long after the fluids have reached thermal equilibrium, the drop persists. By plotting the inverse of the drop radius cubed (r(-)(3)) vs the rotation rate squared (omega(2)), we confirmed that an interfacial tension exists and estimated its value. The transition between the miscible fluids remained sharp instead of becoming more…

SURFACE-TENSIONThermodynamicsGRADIENTSInstabilityIsobutyric acidSurface tensionchemistry.chemical_compoundNONEQUILIBRIUM FLUCTUATIONS1-ButanolIsobutyratesGRAVITYUpper critical solution temperatureElectrochemistrySurface TensionGeneral Materials ScienceSpectroscopyThermal equilibriumAqueous solutionDrop (liquid)ButanolDIFFUSION-COEFFICIENTWaterSurfaces and InterfacesCondensed Matter PhysicsKORTEWEG STRESSESLIGHT-SCATTERINGCAPILLARY TUBESButyrateschemistrySolubilityLIQUID-MIXTURESSYSTEM
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