Regarding viscoelastic effects in elastomeric fracture
ORAL
Abstract
In our initial investigations of elastomeric fracture [1], we stayed in elastic limit where stress-strain curves overlap, independent of rate and temperature. In this limit there is no correlation between temperature dependence of toughness and that of dynamic modulus, yet there is strong temperature and rate dependencies, which can only be explained by acknowledging bond dissociation as the controlling event in fracture [2]. In this study, we move into viscoelastic regime and investigate how our formulation of elastomeric fracture needs to be generalized.
[1] Fan, Z.; Wang, S.-Q. Resolving stress state at crack tip to elucidate nature of elastomeric fracture. Extreme Mechanics Letters 2023, 62, 101986.
[2] Wang, S.-Q.; Fan, Z. Investigating dependence of elastomeric fracture on temperature and rate. Rubber Chem. Technol. 2023, in press.
[1] Fan, Z.; Wang, S.-Q. Resolving stress state at crack tip to elucidate nature of elastomeric fracture. Extreme Mechanics Letters 2023, 62, 101986.
[2] Wang, S.-Q.; Fan, Z. Investigating dependence of elastomeric fracture on temperature and rate. Rubber Chem. Technol. 2023, in press.
* This work is supported, in part, by the Polymers program at the US National Science Foundation (DMR-2210184).
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Presenters
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Shi-Qing Wang
University of Akron
Authors
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Shi-Qing Wang
University of Akron
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Zehao Fan
The University of Akron, University of Akron
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Asal YousefiSiavoshani
University of Akron
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Junpeng Wang
University of Akron
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Ming-Chi Wang
University of Akron