International Journal of Extreme Manufacturing, Volume. 7, Issue 2, 25504(2025)
3D-programmable streamline guided orientation in composite materials for targeted heat dissipation
[1] [1] Mecklenburg M, Mizushima D, Ohtake N, Bauhofer W, Fiedler B and Schulte K 2015 On the manufacturing and electrical and mechanical properties of ultra-high wt.% fraction aligned MWCNT and randomly oriented CNT epoxy compositesCarbon91275–90
[2] [2] Anand S, Vu M C, Mani D, Kim J-B, Jeong T-H, Islam A and Kim S-R 2023 Dual 3D networks of graphene derivatives based polydimethylsiloxane composites for electrical insulating electronic packaging materials with outstanding electromagnetic interference shielding and thermal dissipation performancesChem. Eng. J.462142017
[3] [3] Huang T Q, Wang T, Jin J, Chen M and Wu L M 2023 Design of silicon rubber/BN film with high through-plane thermal conductivity and ultra-low contact resistanceChem. Eng. J.469143874
[4] [4] Li C, Zeng X-L, Tan L-Y, Yao Y-M, Zhu D-L, Sun R, Xu J-B and Wong C-P 2019 Three-dimensional interconnected graphene microsphere as fillers for enhancing thermal conductivity of polymerChem. Eng. J.36879–87
[5] [5] Coleman J N, Khan U, Blau W J and Gun'ko Y K 2006 Small but strong: a review of the mechanical properties of carbon nanotube–polymer compositesCarbon441624–52
[6] [6] Zhang X-D, Yang G and Cao B-Y 2022 Bonding-enhanced interfacial thermal transport: mechanisms, materials, and applicationsAdv. Mater. Interfaces92200078
[7] [7] Peng L Q, Yu H T, Chen C, He Q X, Zhang H, Zhao F L, Qin M M, Feng F Y and Feng W 2023 Tailoring dense, orientation-tunable, and interleavedly structured carbon-based heat dissipation platesAdv. Sci.102205962
[8] [8] Mao D S, Chen J H, Ren L L, Zhang K, Yuen M M F, Zeng X L, Sun R, Xu J-B and Wong C-P 2019 Spherical core-shell Al@Al2O3filled epoxy resin composites as high-performance thermal interface materialsComposiesA123260–9
[9] [9] Kim Y-K, Chung J-Y, Lee J-G, Baek Y-K and Shin P-W 2017 Synergistic effect of spherical Al2O3 particles and BN nanoplates on the thermal transport properties of polymer compositesComposiesA98184–91
[10] [10] Oya T, Nomura T, Tsubota M, Okinaka N and Akiyama T 2013 Thermal conductivity enhancement of erythritol as PCM by using graphite and nickel particlesAppl. Therm. Eng.61825–8
[11] [11] Xie B, Zhao W X, Luo X B and Hu R 2023 Alignment engineering in thermal materialsMater. Sci. Eng.R154100738
[12] [12] Lei C X, Xie Z L, Wu K and Fu Q 2021 Controlled vertically aligned structures in polymer composites: natural inspiration, structural processing, and functional applicationAdv. Mater.332103495
[13] [13] Karthik M, Faik A, Blanco-Rodrguez P, Rodrguez-Aseguinolaza J and D'Aguanno B 2015 Preparation of erythritol-graphite foam phase change composite with enhanced thermal conductivity for thermal energy storage applicationsCarbon94266–76
[14] [14] Zhang X-D, Zhang Z-T, Wang H-Z and Cao B-Y 2023 Thermal interface materials with high thermal conductivity and low young's modulus using a solid-liquid metal codoping strategyACS Appl. Mater. Interfaces153534–42
[15] [15] Yu Z F, Wei S and Guo J D 2019 Fabrication of aligned carbon-fiber/polymer TIMs using electrostatic flocking methodJ. Mater. Sci., Mater. Electron.3010233–43
[16] [16] Uetani K, Ata S, Tomonoh S, Yamada T, Yumura M and Hata K 2014 Elastomeric thermal interface materials with high through-plane thermal conductivity from carbon fiber fillers vertically aligned by electrostatic flockingAdv. Mater.265857–62
[17] [17] Kargar F, Barani Z, Salgado R, Debnath B, Lewis J S, Aytan E, Lake R K and Balandin A A 2018 Thermal percolation threshold and thermal properties of composites with high loading of graphene and boron nitride fillersACS Appl. Mater. Interfaces1037555–65
[18] [18] Nikzad M, Masood S H and Sbarski I 2011 Thermo-mechanical properties of a highly filled polymeric composites for fused deposition modelingMater. Des.323448–56
[19] [19] Yuan C, Huang M Y, Cheng Y H and Luo X B 2017 Bonding-induced thermal transport enhancement across a hard/soft material interface using molecular monolayersPhys. Chem. Chem. Phys.197352–8
[20] [20] Majumdar S, Sierra-Suarez J A, Schiffres S N, Ong W-L, Higgs C F III McGaughey A J H and Malen J A 2015 Vibrational mismatch of metal leads controls thermal conductance of self-assembled monolayer junctionsNano Lett.152985–91
[21] [21] Chen J, Huang X Y, Sun B and Jiang P K 2019 Highly thermally conductive yet electrically insulating polymer/boron nitride nanosheets nanocomposite films for improved thermal management capabilityACS Nano13337–45
[22] [22] Zhang X, Jiang J Y, Shen Z H, Dan Z K, Li M, Lin Y H, Nan C-W, Chen L Q and Shen Y 2018 Polymer nanocomposites with ultrahigh energy density and high discharge efficiency by modulating their nanostructures in three dimensionsAdv. Mater.301707269
[23] [23] Yuan C, Duan B, Li L, Xie B, Huang M Y and Luo X B 2015 Thermal conductivity of polymer-based composites with magnetic aligned hexagonal boron nitride plateletsACS Appl. Mater. Interfaces713000–6
[24] [24] Zhang X F, Zhou S L, Xie B, Lan W, Fan Y W, Hu R and Luo X B 2021 Thermal interface materials with sufficiently vertically aligned and interconnected nickel-coated carbon fibers under high filling loads made via preset-magnetic-field methodCompos. Sci. Technol.213108922
[25] [25] Zhang X, Wu K, Liu Y H, Yu B W, Zhang Q, Chen F and Fu Q 2019 Preparation of highly thermally conductive but electrically insulating composites by constructing a segregated double network in polymer compositesCompos. Sci. Technol.175135–42
[26] [26] Xie K, Liu Y H, Tian Y X, Wu X N, Wu L Y, Mo Y L, Sui G, Du R N, Fu Q and Chen F 2021 Improving the flexibility of graphene nanosheets films by using aramid nanofiber frameworkComposiesA142106265
[27] [27] Zhang X F, Xie B, Zhou S L, Yang X, Fan Y W, Hu R and Luo X B 2022 Radially oriented functional thermal materials prepared by flow field-driven self-assembly strategyNano Energy104107986
[28] [28] Zhang Jet al2017 A facile method to prepare flexible boron nitride/poly (vinyl alcohol) composites with enhanced thermal conductivityCompos. Sci. Technol.14941–47
[29] [29] Zeng X L, Yao Y M, Gong Z Y, Wang F F, Sun R, Xu J B and Wong C-P 2015 Ice-templated assembly strategy to construct 3D boron nitride nanosheet networks in polymer composites for thermal conductivity improvementSmall116205–13
[30] [30] Wang C H, Chen X, Wang B, Huang M, Wang B, Jiang Y and Ruoff R S 2018 Freeze-casting produces a graphene oxide aerogel with a radial and centrosymmetric structureACS Nano125816–25
[31] [31] Liu D Y, Lei C X, Wu K and Fu Q 2020 A multidirectionally thermoconductive phase change material enables high and durable electricityviareal-environment solar-thermal-electric conversionACS Nano1415738–47
[32] [32] Xie B, Wang Y J, Liu H C, Ma J L, Zhou S L, Yu X J, Lan W, Wang K, Hu R and Luo X B 2022 Targeting cooling for quantum dots by 57.3 ℃ with air-bubbles-assembled three-dimensional hexagonal boron nitride heat dissipation networksChem. Eng. J.427130958
[33] [33] Erb R M, Libanori R, Rothfuchs N and Studart A R 2012 Composites reinforced in three dimensions by using low magnetic fieldsScience335199–204
[34] [34] Moore A L and Shi L 2014 Emerging challenges and materials for thermal management of electronicsMater. Today17163–74
[35] [35] Li J C, Li F Z, Zhao X Y, Zhang W F, Li S J, Lu Y L and Zhang L Q 2020 Jelly-inspired construction of the three-dimensional interconnected BN network for lightweight, thermally conductive, and electrically insulating rubber compositesACS Appl. Electron. Mater.21661–9
[36] [36] Kokkinis D, Schaffner M and Studart A R 2015 Multimaterial magnetically assisted 3D printing of composite materialsNat. Commun.68643
[37] [37] Compton B G and Lewis J A 2014 3D-printing of lightweight cellular compositesAdv. Mater.265930–5
[38] [38] Cho D, Choi Y, Park J K, Lee J, Yoon B I and Lim Y S 2004 Thermal conductivity and thermal expansion behavior of pseudo-unidirectional and 2-directional quasi-carbon fiber/phenolic compositesFibers Polym.531–38
[39] [39] Lalet G, Kurita H, Heintz J-M, Lacombe G, Kawasaki A and Silvain J-F 2014 Thermal expansion coefficient and thermal fatigue of discontinuous carbon fiber-reinforced copper and aluminum matrix composites without interfacial chemical bondJ. Mater. Sci.49397–402
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Zhang Xinfeng, Yang Xuan, Fan Yiwen, Hu Run, Xie Bin, Luo Xiaobing. 3D-programmable streamline guided orientation in composite materials for targeted heat dissipation[J]. International Journal of Extreme Manufacturing, 2025, 7(2): 25504
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Received: Feb. 5, 2024
Accepted: May. 29, 2025
Published Online: May. 29, 2025
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