A minimal explicit-solvent lattice model with quenched disorder produces UCST, closed-loop, and reentrant phase transitions plus complex morphologies in protein solutions and binary mixtures, modulated by interaction parameters.
Shin \ and\ author C
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cond-mat.soft 3years
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Tensile tests on a 16-bead colloidal ribbon reveal multiple deformation modes up to fracture at ~10% strain, reproduced by a spring-mass model with full and reduced Monte Carlo simulations.
Brownian dynamics simulations demonstrate that multi-scale chromatin fiber geometry and network organization control the positioning, size, morphology, and multiplicity of liquid-liquid phase separated condensates via protein-fiber interactions.
citing papers explorer
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Liquid-Liquid Phase Separation in a Minimal Explicit-Solvent Lattice Model Mimicking Protein Solutions
A minimal explicit-solvent lattice model with quenched disorder produces UCST, closed-loop, and reentrant phase transitions plus complex morphologies in protein solutions and binary mixtures, modulated by interaction parameters.
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Mechanical response of quasi-two-dimensional colloidal clusters under uniaxial tension
Tensile tests on a 16-bead colloidal ribbon reveal multiple deformation modes up to fracture at ~10% strain, reproduced by a spring-mass model with full and reduced Monte Carlo simulations.
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A Brownian dynamics study of liquid-liquid phase separation in multi-scale chromatin networks
Brownian dynamics simulations demonstrate that multi-scale chromatin fiber geometry and network organization control the positioning, size, morphology, and multiplicity of liquid-liquid phase separated condensates via protein-fiber interactions.