Dielectric and Shear-Mechanical “Humps” in the Nonlinear Response of Polar Glassformers

Kevin Moch; Catalin Gainaru; Roland Böhmer

doi:10.1021/acs.jpcb.4c04528

Dielectric and Shear-Mechanical “Humps” in the Nonlinear Response of Polar Glassformers

Kevin Moch
, Catalin Gainaru
, Roland Böhmer

Soft Materials and Membranes

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Many glassformers display electrorheological effects and a pronounced maximum in their frequency dependent nonlinear dielectric response. The latter so-called “hump” feature was often linked to correlated-particle motions and, so far, was not explored in the large-perturbation mechanical response of viscous liquids. To first clarify the electro-viscoelastic coupling in the linear domain, using the modified Gemant, DiMarzio, and Bishop model, it is demonstrated how the small-amplitude shear mechanical response of S-methoxy-PC, a derivative of propylene carbonate, can be related to its complex dielectric permittivity. Then, in the nonlinear regime, a “hump” feature is identified in the rheological third-order shear modulus of S-methoxy-PC and of another polar glassformer, propylene glycol. Thus, the observation of a “hump” in the cubic response of viscous liquids does not necessarily rely on the application of electrical fields.

Original language	English
Pages (from-to)	8846-8854
Number of pages	9
Journal	Journal of Physical Chemistry B
Volume	128
Issue number	36
DOIs	https://doi.org/10.1021/acs.jpcb.4c04528
State	Published - Sep 12 2024

Funding

The financial support provided by the Deutsche Forschungsgemeinschaft, grant no. 461147152, is gratefully acknowledged.

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10.1021/acs.jpcb.4c04528

Cite this

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title = "Dielectric and Shear-Mechanical “Humps” in the Nonlinear Response of Polar Glassformers",

abstract = "Many glassformers display electrorheological effects and a pronounced maximum in their frequency dependent nonlinear dielectric response. The latter so-called “hump” feature was often linked to correlated-particle motions and, so far, was not explored in the large-perturbation mechanical response of viscous liquids. To first clarify the electro-viscoelastic coupling in the linear domain, using the modified Gemant, DiMarzio, and Bishop model, it is demonstrated how the small-amplitude shear mechanical response of S-methoxy-PC, a derivative of propylene carbonate, can be related to its complex dielectric permittivity. Then, in the nonlinear regime, a “hump” feature is identified in the rheological third-order shear modulus of S-methoxy-PC and of another polar glassformer, propylene glycol. Thus, the observation of a “hump” in the cubic response of viscous liquids does not necessarily rely on the application of electrical fields.",

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AU - Moch, Kevin

AU - Gainaru, Catalin

AU - Böhmer, Roland

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AB - Many glassformers display electrorheological effects and a pronounced maximum in their frequency dependent nonlinear dielectric response. The latter so-called “hump” feature was often linked to correlated-particle motions and, so far, was not explored in the large-perturbation mechanical response of viscous liquids. To first clarify the electro-viscoelastic coupling in the linear domain, using the modified Gemant, DiMarzio, and Bishop model, it is demonstrated how the small-amplitude shear mechanical response of S-methoxy-PC, a derivative of propylene carbonate, can be related to its complex dielectric permittivity. Then, in the nonlinear regime, a “hump” feature is identified in the rheological third-order shear modulus of S-methoxy-PC and of another polar glassformer, propylene glycol. Thus, the observation of a “hump” in the cubic response of viscous liquids does not necessarily rely on the application of electrical fields.

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Dielectric and Shear-Mechanical “Humps” in the Nonlinear Response of Polar Glassformers

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