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Hauptverfasser: van Lange, Sophie G. M., Brake, Diane W. te, Brink, Eline F., Pees, Jochem, van Nieuwenhuijzen, Mathilde M., Vengallur, Nayan, Zaccone, Alessio, Giuntoli, Andrea, Sprakel, Joris, van der Gucht, Jasper
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2509.06042
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author van Lange, Sophie G. M.
Brake, Diane W. te
Brink, Eline F.
Pees, Jochem
van Nieuwenhuijzen, Mathilde M.
Vengallur, Nayan
Zaccone, Alessio
Giuntoli, Andrea
Sprakel, Joris
van der Gucht, Jasper
author_facet van Lange, Sophie G. M.
Brake, Diane W. te
Brink, Eline F.
Pees, Jochem
van Nieuwenhuijzen, Mathilde M.
Vengallur, Nayan
Zaccone, Alessio
Giuntoli, Andrea
Sprakel, Joris
van der Gucht, Jasper
contents Supercooled liquids undergo a rapid change in dynamics as they are cooled to their glass transition temperature and turn from a flowing liquid into an amorphous solid. Depending on how steeply the viscosity changes with temperature around the glass transition, glass formers are classified as strong or fragile. An empirical relation exists between the fragility of the liquid and the broadness of its relaxation spectrum. However, the microscopic origins of this correlation remain unclear and its generality has been debated\cite. Here, we demonstrate that this relationship is inverted in organic materials with ionic interactions. We introduce a novel class of materials consisting of highly charged hydrophobic polymers cross-linked via moderated ionic interactions, and show that these combine a strong glass transition with an unusually broad mechanical relaxation spectrum. By surveying a large variety of ionic liquids, polymerized ionic liquids, and ionomers, we show that all these charged materials follow a trend between fragility and relaxation broadness that is opposite to that of non-charged materials. This finding suggests a special role of long-ranged ionic interactions in vitrification and opens up a route toward developing new materials that combine the processability of strong glass formers with the mechanical dissipation of polymers.
format Preprint
id arxiv_https___arxiv_org_abs_2509_06042
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ionic glass formers show an inverted relation between fragility and relaxation broadness
van Lange, Sophie G. M.
Brake, Diane W. te
Brink, Eline F.
Pees, Jochem
van Nieuwenhuijzen, Mathilde M.
Vengallur, Nayan
Zaccone, Alessio
Giuntoli, Andrea
Sprakel, Joris
van der Gucht, Jasper
Soft Condensed Matter
Supercooled liquids undergo a rapid change in dynamics as they are cooled to their glass transition temperature and turn from a flowing liquid into an amorphous solid. Depending on how steeply the viscosity changes with temperature around the glass transition, glass formers are classified as strong or fragile. An empirical relation exists between the fragility of the liquid and the broadness of its relaxation spectrum. However, the microscopic origins of this correlation remain unclear and its generality has been debated\cite. Here, we demonstrate that this relationship is inverted in organic materials with ionic interactions. We introduce a novel class of materials consisting of highly charged hydrophobic polymers cross-linked via moderated ionic interactions, and show that these combine a strong glass transition with an unusually broad mechanical relaxation spectrum. By surveying a large variety of ionic liquids, polymerized ionic liquids, and ionomers, we show that all these charged materials follow a trend between fragility and relaxation broadness that is opposite to that of non-charged materials. This finding suggests a special role of long-ranged ionic interactions in vitrification and opens up a route toward developing new materials that combine the processability of strong glass formers with the mechanical dissipation of polymers.
title Ionic glass formers show an inverted relation between fragility and relaxation broadness
topic Soft Condensed Matter
url https://arxiv.org/abs/2509.06042