Polydispersity and gelation in concentrated colloids with competing interactions

Publication date

2015-01-14

Authors

Zhang, Tian Hui
Kuipers, B.W.M.ORCID 0000-0002-0300-7190ISNI 0000000393666452
Tian, Wen De
Groenewold, J.ISNI 0000000368859906
Kegel, W.K.ISNI 0000000388841893

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Article
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Abstract

In colloids with competing short-range attractions and long-range repulsions, microcrystalline gels are experimentally formed under conditions where computer simulations point to a lamellar phase as the ground state. Here, upon applying a low-frequency alternating electric field, we bring the system from an initial gel state to a columnar-like state. While molecular dynamics simulations on monodisperse colloids reveal that a columnar structure spontaneously evolves towards a lamellar phase, the columnar-like state in experiments relaxes back to the initial disordered gel state once the electric field is switched off. Similarly, a columnar phase in molecular dynamics simulations decomposes into finite-size crystalline clusters as the relative polydispersity of the colloids is around 1.0%. We conclude that the experimentally observed melting of the columnar structure is driven by polydispersity. Moreover, further simulations reveal that the critical polydispersity required to destabilize a long-range ordered structure increases with the attraction range, pointing to the possibility of observing periodic structures in experiments if the attraction range is sufficiently long compared to the polydispersity of the colloids.

Keywords

General Chemistry, Condensed Matter Physics

Citation

Zhang, T H, Kuipers, B W M, Tian, W D, Groenewold, J & Kegel, W K 2015, 'Polydispersity and gelation in concentrated colloids with competing interactions', Soft Matter, vol. 11, no. 2, pp. 297-302. https://doi.org/10.1039/c4sm02273d