Manipulating the Thermal Conductivity of the Graphene/Poly(vinyl alcohol) Composite via Surface Functionalization: A Multiscale Simulation

Yang, Shi Chun; Zhang, Wenfeng; Ma, Ruibin; Li, Haoxiang; Xinyi, Lin; Zhao, Xiuying; Zhang, Liqun; Gao, Yangyang

doi:10.1021/acs.langmuir.3c00677

Cited by 2 publications

(2 citation statements)

References 66 publications

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“…The impact of chemical bonds and size of GE on the thermal conductivity of a GE/polyamide composite is studied, which is significantly enhanced when all the GE with a large size are covalently bonded . However, the functionalization or defects in the GE fillers will lead to a reduction in the intrinsic thermal conductivity of GE, which is due to the shortening of the phonon mean free path. − This subsequently results in a lower heat transport efficiency of the composites. Nevertheless, the precise impact of defects on the overall thermal conductivity of the composites remains unclear.…”

Section: Introductionmentioning

confidence: 99%

“…According to the current progress, a large number of GE fillers are necessary to realize the high thermal conductivity of composite. − The thermal network of GE will be formed at a high volume fraction, which will determine the thermal conductivity of the composites. However, the intricate relationship between the network structure of GE and the thermal conductivity of the composite remains poorly understood, which is primarily dominated by the GE–GE interfacial thermal resistance (ITR) and the intrinsic thermal conductivity of GE.…”

Section: Introductionmentioning

confidence: 99%

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Thermal Conductivity of the Graphene/Polydimethylsiloxane Composite by Manipulating the Network Structure

Gao,

Hu,

Zhang

et al. 2024

Langmuir

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In this work, a nonequilibrium molecular dynamics simulation is utilized to explore the effect of network structure of graphene (GE) on the thermal conductivity of the GE/polydimethylsiloxane (PDMS) composite. First, the thermal conductivity of composites rises with increasing volume fraction of GE. The heat transfer ability via the GE channel is found to be nearly the same by analyzing the GE−GE interfacial thermal resistance (ITR). More heat energy is transferred via the GE channel at the high volume fraction of GE by calculating the GE heat transfer ratio, which leads to the high thermal conductivity. Then, the thermal conductivity of composites rises with increasing stacking area between GE, which is attributed to both the strong heat transfer ability via the GE channel and the high GE heat transfer ratio. Following it, the thermal conductivity of composites first rises and then drops down with increasing defect density for a single vacancy defect while it continuously increases for a single void defect. The heat transfer ability between GE is enhanced due to the formation of interlayer covalent bonds. However, the intrinsic thermal conductivity of GE is significantly reduced for a single vacancy defect while it remains relatively well for a single void defect. As a result, the GE heat transfer ratio is maximum at the intermediate defect density for a single vacancy defect while it rises monotonically for a single void defect, which can rationalize the thermal conductivity. Meanwhile, the relationship between ITR and the number of covalent bonds can be described by an empirical equation. Finally, the thermal conductivity for the stacked structure is larger than that for the noncontact structure or the intersected structure. In summary, this work provides a clear and novel understanding of how the network structure of GE influences the thermal conductivity of the GE/PDMS composite.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermal Conductivity of the Graphene/Polydimethylsiloxane Composite by Manipulating the Network Structure

Gao,

Hu,

Zhang

et al. 2024

Langmuir

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Nanocomposite nanofibrous membranes of graphene and graphene oxide: water remediation potential

Kausar,

Ahmad,

Lam

2024

Pure and Applied Chemistry

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Immense research efforts on graphene or graphene oxide have led to the formation of unique nanocarbon derived nanomaterials. Graphene and graphene oxide have been reinforced in polymeric matrices to form high performance nanocomposites. Significant applications of polymer nanocomposites with graphene or graphene oxide were experiential for nanofiber formation and ensuing membranes. This overview highlights design, essential features, and potential of graphene or graphene oxide derived nanocomposite nanofibrous membranes for water remediation permeation towards contaminates, salts, toxins, microbials, and other separation purposes. Here, polymer filled graphene or graphene oxide nanocomposites have been processed into nanofibers using appropriate techniques such as electrospinning, wet spinning, template method, etc. Afterwards, polymer/graphene and polymer/graphene oxide nanofiber nanocomposites were applied to form the nanocomposite membranes using appropriate techniques like solution processing, casting methods, infiltration, etc. Consequently, high performance membranes have been researched for technological purposes, especially water management competence. Future research on polymer/graphene nanofibrous membranes may lead to highly efficient systems for commercial and industrial level uses.

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Manipulating the Thermal Conductivity of the Graphene/Poly(vinyl alcohol) Composite via Surface Functionalization: A Multiscale Simulation

Cited by 2 publications

References 66 publications

Thermal Conductivity of the Graphene/Polydimethylsiloxane Composite by Manipulating the Network Structure

Thermal Conductivity of the Graphene/Polydimethylsiloxane Composite by Manipulating the Network Structure

Nanocomposite nanofibrous membranes of graphene and graphene oxide: water remediation potential

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