Spontaneous biaxial pattern generation and autonomous wetting switching on the surface of gold/shape memory polystyrene bilayer

et al. 2018

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We present a phenomenological model for dynamic deformation and mechanical response of double-network (with short-chained ionic network and long-chained covalent network) hydrogel composite based on theory of transient networks. Molecular structures and stress-strain relations of the hydrogel composite were investigated based on thermomechanical properties of the individual network. Constitutive relations were derived for its nonlinear viscoelastic responses and annihilation/reformation rates of active short chains were determined by means of Eyring formula. An extended Volokh model was proposed to separate effects of large strain hysteresis and anomalous viscoelastic relaxation on the hydrogel composite after strain reversal. Experimental results from rate-independent tests are well in agreement with that of the numerical simulations. This study provides a fundamental simulation tool for modelling and predicting mechanics and mechanisms of viscoelastic response and mechanical responses in double-network hydrogel composite.

Section: Introductionmentioning

confidence: 99%

A phenomenological model for dynamic response of double-network hydrogel composite undergoing transient transition

Wang

et al. 2018

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“…SMPs exhibit unique thermodynamics properties and respond to the environmental and temperature changes. They were often characterized using dynamic mechanical analysis (DMA) tests, and thus the viscoelastic behavior was often expressed as a function of storage modulus [28][29][30]. Therefore, storage modulus is a key function to reflect the thermomechanical properties of SMPs.…”

Section: Viscoelastic Behavior and Theoretical Modeling Of Smementioning

confidence: 99%

A thermomechanical model of multi-shape memory effect for amorphous polymer with tunable segment compositions

Wang

et al. 2019

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Multi-shape memory effect (multi-SME) in amorphous polymers has attracted great attention due to their complex thermal transitions and multi-step recovery behavior. Many experimental studies have been reported for synthesis, characterization, testing and demonstration of the multi-SME. However, theoretical approaches have seldom been applied although they are critically needed to understand the principles and predict the behavior of the multi-SME in various amorphous polymers. In this study, a new thermomechanical model was proposed to describe the thermo-/chemo-responsive multi-SME of amorphous polymers with tunable segment compositions. Based on the Weibull statistical model, a new constitutive framework was established to describe temperature-, stretch ratio-and strain-dependent behaviors of thermo-/chemo-responsive multi-SME. Finally, this newly proposed model was applied to quantitatively identify the crucial factors for the thermo-/chemo-responsive shape recovery behaviors, which have been verified by the reported experimental data.

“…Understanding the chemical responses of polymers to mechanical loading are crucial for wide-range research areas in polymer science and technology, as well as for designs of new types of stress-responsive and energy-transduction polymers [1][2][3]. Mechanical loading, i.e., using high pressure, mechanical forces or ultrasound [4][5][6], provides an effective stimulus approach for chemists to design/fabricate novel materials [7][8][9], similar to those using heat, light or electricity [10][11][12]. Various types of stress-responsive and energy-transduction polymers have been produced based on the chemical reactions of molecule bonds in response to the external stresses or forces, including flow-induced mechanochemistry of polymers in solution [13], mechanically-induced dichroism [14,15] and ultrasonication-induced chain scissions in polymers [16].…”

Section: Introductionmentioning

confidence: 99%

A strategy for modelling mechanochemically induced unzipping and scission of chemical bonds in double-network polymer composite

et al. 2019

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A molecular mechanics model for covalent and ionic double-network polymer composites was developed in this study to investigate mechanisms of mechanochemically induced unzipping and scission of chemical bonds. Morse potential function was firstly applied to investigate mechanical unzipping of the covalent bonds, and then stress-dependent mechanical energy for the interatomic covalent bonds was discussed. A new mechanochemical model was formulated for describing the mechanically induced ionic bond scissions based on the Morse potential model and equations for electrostatic forces. Based on this newly proposed model, mechanochemical behaviors of several common interatomic interaction types (e.g.of the ionic bonds have been quantitatively described and analyzed. Finally, mechanochemical unzipping of the covalent bonds and dissociation of the ionic bonds have been characterized and analyzed based on the molecular mechanics model, which has well predicted the chemical and mechanochemical activations in the covalent and ionic double-network polymer 2 composites.