Increased Thermal Conductivity of Eicosane-Based Composite Phase Change Materials in the Presence of Graphene Nanoplatelets

Fang, Xin; Fan, Li‐Wu; Ding, Qianshan; Wang, Xiao; Yao, Xiao-Li; Hou, Jian-Feng; Yu, Zhonghua; Cheng, Guanhua; Hu, Ya-Cai; Cen, Kefa

doi:10.1021/ef400702a

Cited by 209 publications

(77 citation statements)

References 34 publications

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“…In recent years, carbon based fillers, such as graphite, carbon nanofibers, carbon nanotubes, and graphene, were used to enhance the thermal conductivity of PCMs because of their excellent thermal conductivity and low density [15][16][17][18][19][20][21][22][23][24][25][26][27]. For example, Shi et al [15] prepared PCMs by mixing paraffin (Tm = 61.6 • C) with exfoliated graphite nanoplatelets (xGnP) or graphene in hot toluene, followed by solvent evaporation and vacuum drying.…”

Section: Introductionmentioning

confidence: 99%

Synergistically-Enhanced Thermal Conductivity of Shape-Stabilized Phase Change Materials by Expanded Graphite and Carbon Nanotube

Liu

Yang

2017

Applied Sciences

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Featured Application: This work faces applications in energy-saving buildings. The involved shape-stabilized phase change material is a promising material used in walls or floors of buildings to regulating the room temperature in a comfortable range, taking advantage of clean and sustainable solar energy or off-peak electricity. Abstract:The thermal conductivity of expanded graphite plate (EGP) and/or multi-wall carbon nanotube (MWCNT)-filled, shape-stabilized, phase change material (SSPCM), based on paraffin, high-density polyethylene (HDPE), and styrene-butadiene-styrene copolymer (SBS), was investigated. The results demonstrated that both EGP and MWCNT increased the thermal conductivity of the SSPCM. EGP showed a greater thermal conductivity improvement than MWCNT. The conductivity of EGP-filled SSPCM reached 0.574 W/mK at 9 wt %, while that of MWCNT was just 0.372 W/mK at the same loading. Furthermore a series of EGP/MWCNT hybrid fillers were prepared and introduced into the SSPCM, and a synergistic effect was observed between the two fillers. When the EGP/MWCNT ratio was 8:2, the most significant thermal conductivity enhancement to the SSPCM was obtained. The thermal conductivity was 0.674 W/mK, 288% that of the SSPCM and 117% that of 9 wt % EGP-filled SSPCM. The SEM photos showed that a bridging of two-dimensional (2D) planar EGP by flexible one-dimensional (1D) MWCNT was constructed. The so-formed EGP-MWCNT network favored heat transfer along it and led to a decreased thermal interface resistance due to the increased EGP-MWCNT junctions.

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Section: Introductionmentioning

confidence: 99%

Synergistically-Enhanced Thermal Conductivity of Shape-Stabilized Phase Change Materials by Expanded Graphite and Carbon Nanotube

Liu

Yang

2017

Applied Sciences

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“…As there are strong π-π interactions between graphene-graphene, the TBR between graphene-graphene can be neglected. However, the TBR between graphene-PMMA must be considered and taken as 1.906 × 10 −8 m 2 K/W [172]. When graphene is oriented along the heat flux, higher K eff values are obtained due to efficient heat transfer channel provided by graphene.…”

Section: Thermal Propertiesmentioning

confidence: 99%

Modeling and Simulation of Graphene Based Polymer Nanocomposites: Advances in the Last Decade

Atif¹,

Inam²

2016

Graphene

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Modeling and simulation allow methodical variation of material properties beyond the capacity of experimental methods. The polymers are one of the most commonly used matrices of choice for composites and have found applications in numerous fields. The stiff and fragile structure of monolithic polymers leads to the innate cracks to cause fracture and therefore the engineering applications of monolithic polymers, requiring robust damage tolerance and high fracture toughness, are not ubiquitous. In addition, when "many-parts" cling together to form polymers, a labyrinth of molecules results, which does not offer to electrons and phonons a smooth and continuous passageway. Therefore, the monolithic polymers are bad conductors of heat and electricity. However, it is well established that when polymers are embedded with suitable entities especially nano-fillers, such as metallic oxides, clays, carbon nanotubes, and other carbonaceous materials, their performance is propitiously improved. Among various additives, graphene has recently been employed as nano-filler to enhance mechanical, thermal, electrical, and functional properties of polymers. In this review, advances in the modeling and simulation of grapheme based polymer nanocomposites will be discussed in terms of graphene structure, topographical features, interfacial interactions, dispersion state, aspect ratio, weight fraction, and trade-off between variables and overall performance.

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“…GNPs are mainly used as an additive to improve mechanical properties and to enhance thermal or electrical conductivity [11][12][13][14]. Specifically, this material is increasingly being used to enhance the thermal conductivity of thermal energy storage media [15,16] such as phase change materials (PCMs). In general the thermal conductivities of most PCMs are very low, leading to problems charging and discharging the storage units.…”

Section: Introductionmentioning

confidence: 99%

The influence of three different intercalation techniques on the microstructure of exfoliated graphite

Heerden

Badenhorst

2015

Carbon

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The characteristics of exfoliated graphite derived from three intercalation methods: gas phase intercalation of iron (III) chloride, modified Hummers method and an electrochemical technique, were compared.Despite the absence of strong oxidizers the electrochemical method produced a material which is very similar to that of the modified Hummers method in virtually every respect. These both produced a graphite oxide based material whilst the gas phase method resulted in a stage 1 intercalation compound. The different materials demonstrated very distinctive exfoliation behaviour.The gas phase material exhibits 3% mass loss during expansion but has a large amount of residual intercalant. The graphite oxide based methods result in mass loss of up to 25% in the expansion zone. For all three samples the residual impurities lead to a reduction in oxidative resistance. Once removed all samples exhibit nearly identical oxidation behaviour.All three methods delivered graphite nanoplatelets with a very high aspect ratio through considerable expansion. Surprisingly the gas phase method caused persistent residual damage. All three methods yielded a product with varying levels of basal and edge damage, but the purified Hummers material exhibited marginally more "ideal" characteristics. The simplest but still effective technique was found to be the electrochemical approach.

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Increased Thermal Conductivity of Eicosane-Based Composite Phase Change Materials in the Presence of Graphene Nanoplatelets

Cited by 209 publications

References 34 publications

Synergistically-Enhanced Thermal Conductivity of Shape-Stabilized Phase Change Materials by Expanded Graphite and Carbon Nanotube

Synergistically-Enhanced Thermal Conductivity of Shape-Stabilized Phase Change Materials by Expanded Graphite and Carbon Nanotube

Modeling and Simulation of Graphene Based Polymer Nanocomposites: Advances in the Last Decade

The influence of three different intercalation techniques on the microstructure of exfoliated graphite

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