Beyond simple self-healing : How anisotropic nanogels adapt their shape to their environment

Nickel, Anne C.; Denton, Alan R.; Houston, Judith E.; Schweins, Ralf; Plivelic, Tomàs S.; Richtering, Walter; Scotti, Andrea

Beyond simple self-healing : How anisotropic nanogels adapt their shape to their environment

Mark

Nickel, Anne C. ; Denton, Alan R. ; Houston, Judith E. ; Schweins, Ralf ; Plivelic, Tomàs S. ^LU ; Richtering, Walter and Scotti, Andrea ^LU (2022) In The Journal of chemical physics 157(19). p.194901-194901

Abstract: The response of soft colloids to crowding depends sensitively on the particles' compressibility. Nanogel suspensions provide model systems that are often studied to better understand the properties of soft materials and complex fluids from the formation of colloidal crystals to the flow of viruses, blood, or platelet cells in the body. Large spherical nanogels, when embedded in a matrix of smaller nanogels, have the unique ability to spontaneously deswell to match their size to that of the nanogel composing the matrix. In contrast to hard colloids, this self-healing mechanism allows for crystal formation without giving rise to point defects or dislocations. Here, we show that anisotropic ellipsoidal nanogels adapt both their size and... (More); The response of soft colloids to crowding depends sensitively on the particles' compressibility. Nanogel suspensions provide model systems that are often studied to better understand the properties of soft materials and complex fluids from the formation of colloidal crystals to the flow of viruses, blood, or platelet cells in the body. Large spherical nanogels, when embedded in a matrix of smaller nanogels, have the unique ability to spontaneously deswell to match their size to that of the nanogel composing the matrix. In contrast to hard colloids, this self-healing mechanism allows for crystal formation without giving rise to point defects or dislocations. Here, we show that anisotropic ellipsoidal nanogels adapt both their size and their shape depending on the nature of the particles composing the matrix in which they are embedded. Using small-angle neutron scattering with contrast variation, we show that ellipsoidal nanogels become spherical when embedded in a matrix of spherical nanogels. In contrast, the anisotropy of the ellipsoid is enhanced when they are embedded in a matrix of anisotropic nanogels. Our experimental data are supported by Monte Carlo simulations that reproduce the trend of decreasing aspect ratio of ellipsoidal nanogels with increasing crowding by a matrix of spherical nanogels.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/75d0e1dc-4697-41d3-83c4-edecf8f7176b

author

Nickel, Anne C. ; Denton, Alan R. ; Houston, Judith E. ; Schweins, Ralf ; Plivelic, Tomàs S. ^LU ; Richtering, Walter and Scotti, Andrea ^LU

organization

MAX IV Laboratory

publishing date

2022-11-21

type

Contribution to journal

publication status

published

subject

Physical Chemistry

in

The Journal of chemical physics

volume

157

issue

19

pages

1 pages

publisher

American Institute of Physics (AIP)

external identifiers

scopus:85142480037
pmid:36414436

ISSN

0021-9606

DOI

10.1063/5.0119527

language

English

LU publication?

yes

id

75d0e1dc-4697-41d3-83c4-edecf8f7176b

date added to LUP

2022-12-27 12:52:30

date last changed

2024-06-27 23:32:56

@article{75d0e1dc-4697-41d3-83c4-edecf8f7176b,
  abstract     = {{<p>The response of soft colloids to crowding depends sensitively on the particles' compressibility. Nanogel suspensions provide model systems that are often studied to better understand the properties of soft materials and complex fluids from the formation of colloidal crystals to the flow of viruses, blood, or platelet cells in the body. Large spherical nanogels, when embedded in a matrix of smaller nanogels, have the unique ability to spontaneously deswell to match their size to that of the nanogel composing the matrix. In contrast to hard colloids, this self-healing mechanism allows for crystal formation without giving rise to point defects or dislocations. Here, we show that anisotropic ellipsoidal nanogels adapt both their size and their shape depending on the nature of the particles composing the matrix in which they are embedded. Using small-angle neutron scattering with contrast variation, we show that ellipsoidal nanogels become spherical when embedded in a matrix of spherical nanogels. In contrast, the anisotropy of the ellipsoid is enhanced when they are embedded in a matrix of anisotropic nanogels. Our experimental data are supported by Monte Carlo simulations that reproduce the trend of decreasing aspect ratio of ellipsoidal nanogels with increasing crowding by a matrix of spherical nanogels.</p>}},
  author       = {{Nickel, Anne C. and Denton, Alan R. and Houston, Judith E. and Schweins, Ralf and Plivelic, Tomàs S. and Richtering, Walter and Scotti, Andrea}},
  issn         = {{0021-9606}},
  language     = {{eng}},
  month        = {{11}},
  number       = {{19}},
  pages        = {{194901--194901}},
  publisher    = {{American Institute of Physics (AIP)}},
  series       = {{The Journal of chemical physics}},
  title        = {{Beyond simple self-healing : How anisotropic nanogels adapt their shape to their environment}},
  url          = {{http://dx.doi.org/10.1063/5.0119527}},
  doi          = {{10.1063/5.0119527}},
  volume       = {{157}},
  year         = {{2022}},
}

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Beyond simple self-healing : How anisotropic nanogels adapt their shape to their environment