Open AccessJammed Limit of Bijel Structure Formation
Author(s) -
Paul M. Welch,
M. N. Lee,
A. Nicholas G. ParraVasquez,
Cynthia Welch
Publication year - 2017
Publication title -
langmuir
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.042
H-Index - 333
eISSN - 1520-5827
pISSN - 0743-7463
DOI - 10.1021/acs.langmuir.7b02805
Subject(s) - spinodal decomposition , spinodal , dimensionless quantity , statistical physics , limit (mathematics) , microstructure , jamming , range (aeronautics) , structure formation , chemical physics , colloid , materials science , thermodynamics , physics , chemistry , mathematics , phase (matter) , crystallography , mathematical analysis , quantum mechanics , galaxy , composite material
Over the past decade, methods to control microstructure in heterogeneous mixtures by arresting spinodal decomposition via the addition of colloidal particles have led to an entirely new class of bicontinuous materials known as bijels. Herein, we present a new model for the development of these materials that yields to both numerical and analytical evaluation. This model reveals that a single dimensionless parameter that captures both chemical and environmental variables dictates the dynamics and ultimate structure formed in bijels. We demonstrate that this parameter must fall within a fixed range in order for jamming to occur during spinodal decomposition, as well as show that known experimental trends for the characteristic domain sizes and time scales for formation are recovered by this model.
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