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Aeolotopic interactions of globular proteins.Unravelling the multilayer growth of the fullerene C60 in real timeA geometrical approach to computing free-energy landscapes from short-ranged potentials.Heads or tails: how do chemically substituted fullerenes melt?Intermolecular potentials--past, present, future.Energetically favoured defects in dense packings of particles on spherical surfaces.Insights into phases of liquid water from study of its unusual glass-forming properties.Self-consistent phonon theory of the crystallization and elasticity of attractive hard spheres.Phase equilibrium of colloidal suspensions with particle size dispersity: a Monte Carlo study.Limits of size scalability of diffusion and growth: Atoms versus molecules versus colloids.Effect of particle size on the glass transition.Theoretical description of phase coexistence in model C60.A cavitation transition in the energy landscape of simple cohesive liquids and glasses.Free energy of singular sticky-sphere clusters.Impact of interaction range and curvature on crystal growth of particles confined to spherical surfaces.Spinodal for the solution-to-crystal phase transformation.Nucleation of ordered solid phases of proteins via a disordered high-density state: phenomenological approach.Multiscale modeling of the surfactant mediated synthesis and supramolecular assembly of cobalt nanodots.Shock-induced phase transition in systems of hard spheres with internal degrees of freedom.Evolution of the liquid-vapor coexistence of the hard-core Yukawa fluid as a function of the interaction range.Effect of the range of attractive interactions on crystallization, metastable phase transition, and percolation in colloidal dispersions.Phase diagram of the hard-core Yukawa fluid within the integral equation method.A general perturbation approach for equation of state development: applications to simple fluids, ab initio potentials, and fullerenes.Metastable liquid-liquid phase transition in a single-component system with only one crystal phase and no density anomaly.Thermophysical properties of gases, liquids, and solids composed of particles interacting with a short-range attractive potential.Phase equilibria and glass transition in colloidal systems with short-ranged attractive interactions: application to protein crystallization.Glass transition in fullerenes: mode-coupling theory predictions.Lennard-Jones potential model for the condensed phases of C70.Liquid-Like Behavior in SolidsSolid-solid and liquid-solid phase equilibria for the restricted primitive modelDetermination of phase diagrams for the hard‐core attractive Yukawa systemIsostructural solid-solid transition in crystalline systems with short-ranged interactionPrediction of an expanded-to-condensed transition in colloidal crystalsPhase behavior and structure of Janus fluidsGlassy colloidal systemsNucleation and growth of C60 nanoparticles from the supersaturated vapor and from the undercooled liquid: A molecular simulation study
P2860
Q30322865-DCBBB074-C577-42CF-8B89-5D0D48567D2CQ30610155-5346D40F-75BA-4A3D-9540-093AD75B4B17Q36512256-D3B4219A-5815-40FB-8764-1B7A2E3A36A7Q39844022-2B36CD0A-DCD3-4BDF-A15F-1AA147EF43DCQ40570974-8AE56B8E-C6A7-4C1B-AFAB-59A05D37A62CQ40718294-774F1AE6-1FE8-44A6-A934-5AD3ED46E3D1Q41611776-69B34E3C-D6C1-47D1-A3F5-A98400569B23Q46720586-4A5DCFB0-36AE-4CBE-B9CF-206D332CFC04Q47182771-2DE7FF5D-90A0-447B-BA7F-7370E6CFED88Q47228346-6BA91254-C6A9-43CA-BA49-AA05C445051EQ47368087-5F0E8F01-F40B-4FBA-A68E-59220AD7C846Q47588536-BC5F5D08-29DB-4D7B-8388-E1482B519C82Q47729840-15A9E70B-EFF3-4F70-8504-4C9B7F9480F8Q47928551-6C1C5252-041D-4B7A-92B0-99276D7BA0B8Q49961401-0A92AF50-DCF2-4008-B55A-9E8F30296533Q51393818-16F40CDA-AAB9-4066-A34B-7E25B8373052Q51457778-5271E255-24F1-47F8-A037-15BAC069F1B7Q51587040-28BB46CA-8F98-439B-B8FA-30153198C01BQ51657194-2B9B5690-E050-41D4-B4A1-57DA5E19D4A0Q51700298-5434DA03-4B14-42C4-9C21-3DB4FF289F2DQ51833030-F56118DF-1F56-4E44-A0B7-A2D6CC82BACCQ51923401-46F09BCE-2D2A-49A4-97E8-5CE81C1CCA17Q51942399-BF4AC432-DFD8-480F-8FE8-63332D1E6346Q52025050-75CCD035-2DA2-443D-A93A-AA95C6A5D44BQ52058843-9FB7FB31-161B-4B10-87F8-434094486DEBQ52414195-6119ECEE-0811-4721-9842-E0AAFCE06FA9Q52854865-2419CC24-E88A-4694-9D62-538DB39456F6Q54001880-D1C4459E-BBDB-46B8-8B58-6C8EE3AE9675Q56932161-8AFE4E26-8D1A-45AA-8E89-82AC22D93D26Q56932204-71869AE9-6445-4F89-9414-771109F37B18Q56932290-6A317172-3EF1-46C3-8A51-E7D5E2AF0F96Q56932304-DF61DDBF-935F-4FAE-A611-341EFADCBD9FQ56932327-3C17F89D-6BBA-497A-A3B0-3A99E0FE312FQ58052093-5416914D-1CFA-451C-85F4-EEC20C583384Q58139288-7F1781C9-6538-4AC2-8879-2783E6468F27Q58347508-987BC4F5-D7D9-48E3-9111-30D755D4CEEB
P2860
description
article publié dans la revue scientifique Nature
@fr
scientific article published in Nature
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в Nature у вересні 1993
@uk
name
Does C60 have a liquid phase?
@en
Does C60 have a liquid phase?
@nl
type
label
Does C60 have a liquid phase?
@en
Does C60 have a liquid phase?
@nl
prefLabel
Does C60 have a liquid phase?
@en
Does C60 have a liquid phase?
@nl
P2093
P356
P1433
P1476
Does C60 have a liquid phase?
@en
P2093
E. J. Meijer
G. C. A. M. Mooij
H. N. W. Lekkerkerker
M. H. J. Hagen
P2888
P304
P356
10.1038/365425A0
P407
P50
P577
1993-09-01T00:00:00Z
P6179
1018148123