Modulating Thermal Transport in Polymers and Interfaces: Theories, Simulations, and Experiments

Zhang, Bo; Peng, Mao; Liang, Yunmin; He, Yan; Liu, Wei; Liu, Zhichun

doi:10.30919/esee8c306

Cited by 20 publications

(24 citation statements)

References 51 publications

(50 reference statements)

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“…Polymer materials have been used widely in many fields, including energy storage and conversion, 1‐6 electromagnetic interference (EMI) shielding, 7 thermal management, 8,9 sensors, 10,11 cryogenic temperature, 12 carbon dioxide adsorption, 13 solar cell, 14 energy savings, 15 micro/nano‐manufacturing technology, 16 flame retardants, 17 injection molding, 18 coating, 16,19 biomedicine, 20,21 flexible electronics, 21 aerospace, 22 automotive, 22 and defense industries 22 and so forth, due to their lightweight, low cost, low density, easy processing and flexible. However, it is common fact for polymer materials that those composites are extremely easy to be damaged due to the internal or external factors of polymer materials in the process of actual working 23‐27 .…”

Section: Introductionmentioning

confidence: 99%

Promoting healing progress in polymer composites based on Diels‐Alder reaction by constructing silver bridges

Ding

Zhang

Zhou

et al. 2020

Polymers for Advanced Techs

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Polymer composites with self‐healing ability are highly desired for applications in advanced modern devices. Here, we report on self‐healing polymer composites consisting of silver deposited‐carbon nanotubes hybrid nanoparticles (CNT‐Ag) as fillers and self‐healable polyurethane (DAPU) as a matrix based on thermally reversible Diels‐Alder reaction. The results indicated that as the hybrid filler loading is 1 wt%, the composites not only obtained a high‐strength (~15.97 MPa) and high healing efficiency (~90.1%) by increasing filler loading after healing, but also enhance thermal conductivity (~1.65 Wm−1 K−1) and obviously shorten its healing progress in comparison with other composites in the case of the same healing time. Given that Ag_NPs deposited on the surfaces of the CNTs act as bridges to link the adjacent CNTs and reduce interfacial thermal resistance, which can effectively explain the reasons for the obtained high mechanical strength and healing efficiency and promoting healing progress in the polymer composites. This work may offer a novel strategy for balancing relation between mechanical property, healing ability and healing progress in the field of self‐healing materials application.

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Section: Introductionmentioning

confidence: 99%

Promoting healing progress in polymer composites based on Diels‐Alder reaction by constructing silver bridges

Ding

Zhang

Zhou

et al. 2020

Polymers for Advanced Techs

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“…Many studies have been conducted on the heat transfer of materials. 44,45 The methods to calculate the thermal conductivity of material by MD simulations mainly include equilibrium molecular dynamics (EMD) and nonequilibrium molecular dynamics (NEMD). 40,46 NEMD has advantages such as fast computation speed and high convergence; thus, in this work, reverse non-equilibrium molecular dynamics (RNEMD) based on NEMD was applied.…”

Section: Calculations Of Thermomechanical Propertiesmentioning

confidence: 99%

Thermomechanical properties of silica–epoxy nanocomposite modified by hyperbranched polyester: A molecular dynamics simulation

Zhang

Wang

et al. 2021

High Performance Polymers

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In this article, pure epoxy resin and silica–epoxy nanocomposite models were established to investigate the effects of hyperbranched polyester on microstructure and thermomechanical properties of epoxy resin through molecular dynamics simulation. Results revealed that the composite of silica can improve the thermomechanical properties of nanocomposites, including the glass transition temperature, thermal conductivity, and elastic modulus. Moreover, the thermomechanical properties were further enhanced through chemical modification on the silica surface, where the effectiveness was the best through grafting hyperbranched polyester on the silica surface. Compared with pure epoxy resin, the glass transition temperature of silica–epoxy composite modified by silica grafted with hyperbranched polyester increased by 38 K. The thermal conductivity increased with the increase of temperature and thermal conductivity at room temperature increased to 0.4171 W/(m·K)−1 with an increase ratio of 94.3%. Young’s modulus, volume modulus, and shear modulus all fluctuated as temperature rise with a down overall trend. They increased by 44.68%, 29.52%, and 36.65%, respectively, when compared with pure epoxy resin. At the same time, the thermomechanical properties were closely related to the microstructure such as fractional free volume (FFV), mean square displacement (MSD), and binding energy. Silica surface modification by grafting hyperbranched polyester reduced the FFV value and MSD value most and strengthened the combination of silica and epoxy resin matrix the best, resulting in the best thermomechanical properties.

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“…The molecular dynamics method, which directly computes the state of every atom and takes the scale effect into consideration, seems to be the most suitable method to investigate the edge mode of graphene sheets compared with finite element methods [34], nonlocal elasticity theory [35,36], and molecular structural mechanics methods [37]. As a computer simulation method for analyzing the movements of atoms and molecules and providing a view of the dynamic "evolution" of the studied system, molecular dynamics has been used to study the mechanical properties [38,39] and thermal properties [40][41][42] of novel nanomaterials including graphene, and the results meet well with those of the experiment.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Edge Mode on Mass Sensing for Strained Graphene Resonators

Xing

Fan

2021

Micromachines

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Edge mode could disturb the ultra-subtle mass detection for graphene resonators. Herein, classical molecular dynamics simulations are performed to investigate the effect of edge mode on mass sensing for a doubly clamped strained graphene resonator. Compared with the fundamental mode, the localized vibration of edge mode shows a lower frequency with a constant frequency gap of 32.6 GHz, despite the mutable inner stress ranging from 10 to 50 GPa. Furthermore, the resonant frequency of edge mode is found to be insensitive to centrally located adsorbed mass, while the frequency of the fundamental mode decreases linearly with increasing adsorbates. Thus, a mass determination method using the difference of these two modes is proposed to reduce interferences for robust mass measurement. Moreover, molecular dynamics simulations demonstrate that a stronger prestress or a higher width–length ratio of about 0.8 could increase the low-quality factor induced by edge mode, thus improving the performance in mass sensing for graphene resonators.

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Modulating Thermal Transport in Polymers and Interfaces: Theories, Simulations, and Experiments

Cited by 20 publications

References 51 publications

Promoting healing progress in polymer composites based on Diels‐Alder reaction by constructing silver bridges

Promoting healing progress in polymer composites based on Diels‐Alder reaction by constructing silver bridges

Thermomechanical properties of silica–epoxy nanocomposite modified by hyperbranched polyester: A molecular dynamics simulation

The Effect of Edge Mode on Mass Sensing for Strained Graphene Resonators

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