Skip to main content

Lund University Publications

LUND UNIVERSITY LIBRARIES

Microgels at Interfaces Behave as 2D Elastic Particles Featuring Reentrant Dynamics

Camerin, Fabrizio LU orcid ; Gnan, Nicoletta ; Ruiz-Franco, José ; Ninarello, Andrea ; Rovigatti, Lorenzo and Zaccarelli, Emanuela (2020) In Physical Review X 10(3).
Abstract

Soft colloids are increasingly used as model systems to address fundamental issues such as crystallization and the glass and jamming transitions. Among the available classes of soft colloids, microgels are emerging as the gold standard. Since their great internal complexity makes their theoretical characterization very hard, microgels are commonly modeled, at least in the small-deformation regime, within the simple framework of linear elasticity theory. Here we show that there exist conditions where its range of validity can be greatly extended, providing strong numerical evidence that microgels adsorbed at an interface follow the two-dimensional Hertzian theory, and hence behave like 2D elastic particles, up to very large deformations,... (More)

Soft colloids are increasingly used as model systems to address fundamental issues such as crystallization and the glass and jamming transitions. Among the available classes of soft colloids, microgels are emerging as the gold standard. Since their great internal complexity makes their theoretical characterization very hard, microgels are commonly modeled, at least in the small-deformation regime, within the simple framework of linear elasticity theory. Here we show that there exist conditions where its range of validity can be greatly extended, providing strong numerical evidence that microgels adsorbed at an interface follow the two-dimensional Hertzian theory, and hence behave like 2D elastic particles, up to very large deformations, in stark contrast to what found in bulk conditions. We are also able to estimate Young's modulus of the individual particles and, by comparing it with its counterpart in bulk conditions, we demonstrate a significant stiffening of the polymer network at the interface. Finally, by analyzing dynamical properties, we predict multiple reentrant phenomena: By a continuous increase of particle density, microgels first arrest and then refluidify due to the high penetrability of their extended coronas. We observe this anomalous behavior in a range of experimentally accessible conditions for small and loosely cross-linked microgels. The present work thus establishes microgels at interfaces as a new model system for fundamental investigations, paving the way for the experimental synthesis and research on unique high-density liquidlike states. In addition, these results can guide the development of novel assembly and patterning strategies on surfaces and the design of novel materials with desired interfacial behavior.

(Less)
Please use this url to cite or link to this publication:
author
; ; ; ; and
publishing date
type
Contribution to journal
publication status
published
in
Physical Review X
volume
10
issue
3
article number
031012
publisher
American Physical Society
external identifiers
  • scopus:85092219625
ISSN
2160-3308
DOI
10.1103/PhysRevX.10.031012
language
English
LU publication?
no
additional info
Publisher Copyright: © 2020 authors.
id
a08920eb-dfc1-4826-b119-f265c312acc4
date added to LUP
2024-02-22 14:12:35
date last changed
2024-02-23 15:59:50
@article{a08920eb-dfc1-4826-b119-f265c312acc4,
  abstract     = {{<p>Soft colloids are increasingly used as model systems to address fundamental issues such as crystallization and the glass and jamming transitions. Among the available classes of soft colloids, microgels are emerging as the gold standard. Since their great internal complexity makes their theoretical characterization very hard, microgels are commonly modeled, at least in the small-deformation regime, within the simple framework of linear elasticity theory. Here we show that there exist conditions where its range of validity can be greatly extended, providing strong numerical evidence that microgels adsorbed at an interface follow the two-dimensional Hertzian theory, and hence behave like 2D elastic particles, up to very large deformations, in stark contrast to what found in bulk conditions. We are also able to estimate Young's modulus of the individual particles and, by comparing it with its counterpart in bulk conditions, we demonstrate a significant stiffening of the polymer network at the interface. Finally, by analyzing dynamical properties, we predict multiple reentrant phenomena: By a continuous increase of particle density, microgels first arrest and then refluidify due to the high penetrability of their extended coronas. We observe this anomalous behavior in a range of experimentally accessible conditions for small and loosely cross-linked microgels. The present work thus establishes microgels at interfaces as a new model system for fundamental investigations, paving the way for the experimental synthesis and research on unique high-density liquidlike states. In addition, these results can guide the development of novel assembly and patterning strategies on surfaces and the design of novel materials with desired interfacial behavior.</p>}},
  author       = {{Camerin, Fabrizio and Gnan, Nicoletta and Ruiz-Franco, José and Ninarello, Andrea and Rovigatti, Lorenzo and Zaccarelli, Emanuela}},
  issn         = {{2160-3308}},
  language     = {{eng}},
  number       = {{3}},
  publisher    = {{American Physical Society}},
  series       = {{Physical Review X}},
  title        = {{Microgels at Interfaces Behave as 2D Elastic Particles Featuring Reentrant Dynamics}},
  url          = {{http://dx.doi.org/10.1103/PhysRevX.10.031012}},
  doi          = {{10.1103/PhysRevX.10.031012}},
  volume       = {{10}},
  year         = {{2020}},
}