Phase separation and dynamical arrest for particles interacting with mixed potentials-the case of globular proteins revisited

Thomas Gibaud; Frederic Cardinaux; Johan Bergenholtz; Anna Stradner; Peter Schurtenberger

doi:10.1039/c0sm01175d

Phase separation and dynamical arrest for particles interacting with mixed potentials-the case of globular proteins revisited

Thomas Gibaud, Frederic Cardinaux, Johan Bergenholtz, Anna Stradner, Peter Schurtenberger

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

We examine the applicability of the extended law of corresponding states (ELCS) to equilibrium and non equilibrium features of the state diagram of the globular protein lysozyme. We provide compelling evidence that the ELCS correctly reproduces the location of the binodal for different ionic strengths, but fails in describing the location of the arrest line. We subsequently use Mode Coupling Theory (MCT) to gain additional insight into the origin of these observations. We demonstrate that while the critical point and the connected binodal and spinodal are governed by the integral features of the interaction potential described by the normalized second virial coefficient, the arrest line is mainly determined by the attractive well depth or bond strength.

Original language	English
Pages (from-to)	857-860
Journal	Soft Matter
Volume	7
Issue number	3
DOIs	https://doi.org/10.1039/c0sm01175d
Publication status	Published - 2011

Bibliographical note

The information about affiliations in this record was updated in December 2015.
The record was previously connected to the following departments: Polymer and Materials Chemistry (LTH) (011001041), Department of Chemistry (011001220)

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Chemical Sciences

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10.1039/c0sm01175d

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title = "Phase separation and dynamical arrest for particles interacting with mixed potentials-the case of globular proteins revisited",

abstract = "We examine the applicability of the extended law of corresponding states (ELCS) to equilibrium and non equilibrium features of the state diagram of the globular protein lysozyme. We provide compelling evidence that the ELCS correctly reproduces the location of the binodal for different ionic strengths, but fails in describing the location of the arrest line. We subsequently use Mode Coupling Theory (MCT) to gain additional insight into the origin of these observations. We demonstrate that while the critical point and the connected binodal and spinodal are governed by the integral features of the interaction potential described by the normalized second virial coefficient, the arrest line is mainly determined by the attractive well depth or bond strength.",

author = "Thomas Gibaud and Frederic Cardinaux and Johan Bergenholtz and Anna Stradner and Peter Schurtenberger",

note = "The information about affiliations in this record was updated in December 2015. The record was previously connected to the following departments: Polymer and Materials Chemistry (LTH) (011001041), Department of Chemistry (011001220)",

year = "2011",

doi = "10.1039/c0sm01175d",

language = "English",

volume = "7",

pages = "857--860",

journal = "Soft Matter",

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TY - JOUR

T1 - Phase separation and dynamical arrest for particles interacting with mixed potentials-the case of globular proteins revisited

AU - Gibaud, Thomas

AU - Cardinaux, Frederic

AU - Bergenholtz, Johan

AU - Stradner, Anna

AU - Schurtenberger, Peter

N1 - The information about affiliations in this record was updated in December 2015. The record was previously connected to the following departments: Polymer and Materials Chemistry (LTH) (011001041), Department of Chemistry (011001220)

PY - 2011

Y1 - 2011

N2 - We examine the applicability of the extended law of corresponding states (ELCS) to equilibrium and non equilibrium features of the state diagram of the globular protein lysozyme. We provide compelling evidence that the ELCS correctly reproduces the location of the binodal for different ionic strengths, but fails in describing the location of the arrest line. We subsequently use Mode Coupling Theory (MCT) to gain additional insight into the origin of these observations. We demonstrate that while the critical point and the connected binodal and spinodal are governed by the integral features of the interaction potential described by the normalized second virial coefficient, the arrest line is mainly determined by the attractive well depth or bond strength.

AB - We examine the applicability of the extended law of corresponding states (ELCS) to equilibrium and non equilibrium features of the state diagram of the globular protein lysozyme. We provide compelling evidence that the ELCS correctly reproduces the location of the binodal for different ionic strengths, but fails in describing the location of the arrest line. We subsequently use Mode Coupling Theory (MCT) to gain additional insight into the origin of these observations. We demonstrate that while the critical point and the connected binodal and spinodal are governed by the integral features of the interaction potential described by the normalized second virial coefficient, the arrest line is mainly determined by the attractive well depth or bond strength.

U2 - 10.1039/c0sm01175d

DO - 10.1039/c0sm01175d

M3 - Article

SN - 1744-6848

VL - 7

SP - 857

EP - 860

JO - Soft Matter

JF - Soft Matter

IS - 3

ER -

Phase separation and dynamical arrest for particles interacting with mixed potentials-the case of globular proteins revisited

Abstract

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