Anisotropic thermal conductivity of aluminum matrix composites reinforced by graphene nanoplates and ZrB2 nanoparticles

Chuang Guan; Xizhou Kai; Wei Qian; Ran Tao; Gang Chen; Yutao Zhao

doi:10.1007/s12613-025-3156-0

International Journal of Minerals, Metallurgy, and Materials ›› 2026, Vol. 33 ›› Issue (2) :636 -646. DOI: 10.1007/s12613-025-3156-0

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Anisotropic thermal conductivity of aluminum matrix composites reinforced by graphene nanoplates and ZrB₂ nanoparticles

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Abstract

This study investigates the anisotropic thermal conductivity of aluminum matrix composites reinforced with graphene nanoplates (GNPs) and in situ ZrB₂ nanoparticles, while simultaneously maintaining high strength and toughness. A discontinuous layered GNPs–ZrB₂/AA6111 composite was prepared using in situ melt reactions and semi-solid stirring casting technology, combined with hot rolling deformation processing. Microstructural analysis revealed that the GNPs were aligned parallel to the rolling direction–transverse direction (RD–TD) plane, whereas the ZrB₂ nanoparticles aggregated into cluster strips, collectively forming a discontinuous layered structure. This multilayer arrangement maximized the in-plane thermal conductivity of the GNPs. The tightly bonded GNP/Al interfaces with the locking of CuAl₂ nanoparticles ensured that the GNPs fully exploited their high thermal conductivity. Therefore, the GNPs–ZrB₂/AA6111 composite achieved high in-plane thermal conductivity (230 W/(m·K)), which is higher than that of the matrix (206 W/(m·K)). The improved in-plane thermal conductivity is primarily attributed to the exceptionally high intrinsic in-plane thermal conductivity of the GNPs and their two-dimensional layered structure. However, the composite exhibited pronounced thermal conductivity anisotropy in the in-plane and through-plane directions. The reduced through-plane thermal conductivity is predominantly caused by the intrinsically low through-plane thermal conductivity of the GNPs and the increased interfacial thermal resistance from the additional grain boundaries.

Keywords

aluminum matrix composites / graphene nanoplates / microstructure / anisotropic thermal conductivity / heat transport mechanisms

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Chuang Guan, Xizhou Kai, Wei Qian, Ran Tao, Gang Chen, Yutao Zhao. Anisotropic thermal conductivity of aluminum matrix composites reinforced by graphene nanoplates and ZrB₂ nanoparticles. International Journal of Minerals, Metallurgy, and Materials, 2026, 33(2): 636-646 DOI:10.1007/s12613-025-3156-0

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Yu J, Geng YX, Chen YKet al.. High-strength and thermally stable TiB₂-modified Al–Mn–Mg–Er–Zr alloy fabricated via selective laser melting. Int. J. Miner. Metall. Mater., 2024, 31102221

[2]	Wang B, Li JW, Xie ZH, Wang GJ, Yu G. High corrosion and wear resistant electroless Ni–P gradient coatings on aviation aluminum alloy parts. Int. J. Miner. Metall. Mater., 2024, 311155

[3]	B.W. Pu, X. Zhang, X.F. Chen, et al., Exceptional mechanical properties of aluminum matrix composites with heterogeneous structure induced by in situ graphene nanosheet–Cu hybrids, Composites Part B, 234(2022), art. No. 109731.

[4]	Bai XR, Xie HN, Zhang Xet al.. Heat-resistant super-dispersed oxide strengthened aluminium alloys. Nat. Mater., 2024, 236747

[5]	X. Wang, Y.W. Xu, Y.H. Li, et al., Rapid detection of cadmium ions in meat by a multi-walled carbon nanotubes enhanced metal-organic framework modified electrochemical sensor, Food Chem., 357(2021), art. No. 129762.

[6]	Yang KM, Ma YC, Zhang ZYet al.. Anisotropic thermal conductivity and associated heat transport mechanism in roll-to-roll graphene reinforced copper matrix composites. Acta Mater., 2020, 197: 342

[7]	Tiwari JK, Mandal A, Rudra A, Mukherjee D, Sathish N. Evaluation of mechanical and thermal properties of bilayer graphene reinforced aluminum matrix composite produced by hot accumulative roll bonding. J. Alloy. Compd., 2019, 801: 49

[8]	B. Hou, P. Liu, A.Q. Wang, and J.P. Xie, Interface optimization strategy for enhancing the mechanical and thermal properties of aligned graphene/Al composite, J. Alloy. Compd., 900(2022), art. No. 163555.

[9]	S.H. Wu, H.S. Soreide, B. Chen, et al., Freezing solute atoms in nanograined aluminum alloys via high-density vacancies, Nat. Commun., 13(2022), No. 1, art. No. 3495.

[10]	Sun LG, Wu G, Wang Q, Lu J. Nanostructural metallic materials: Structures and mechanical properties. Mater. Today, 2020, 38: 114

[11]	Yang S, Sun ZR, Wang ZPet al.. Microstructural optimization and strengthening mechanisms of in-situ TiB₂/Al–Cu composite after multidirectional forging for six passes. Int. J. Miner. Metall. Mater., 2025, 3271703

[12]	H.R. Yang, J.W. Sha, D.D. Zhao, et al., Defects control of aluminum alloys and their composites fabricated via laser powder bed fusion: A review, J. Mater. Process. Technol., 319(2023), art. No. 118064.

[13]	V. Singh, A. Sharma G.K. Gupta, et al., Evolution of Microstructure and mechanical properties of graphene oxide reinforced aluminum alloy 6061 composite fabricated by accumulative roll bonding, Int. J. Miner. Metall. Mater., (2025). DOI: https://doi.org/10.1007/s12613-025-3194-7

[14]	Miranda A, Barekar N, McKay BJ. MWCNTs and their use in Al–MMCs for ultra-high thermal conductivity applications: A review. J. Alloy. Compd., 2019, 774: 820

[15]	Sharma AS, Ali S, Sabarinathan D, Murugavelu M, Li H, Chen Q. Recent progress on graphene quantum dots-based fluorescence sensors for food safety and quality assessment applications. Compr. Rev. Food Sci. Food Saf., 2021, 2065765

[16]	Y.H. Li, Y.X. Li, D. Zhang, et al., A fluorescence resonance energy transfer probe based on functionalized graphene oxide and upconversion nanoparticles for sensitive and rapid detection of zearalenone, LWT, 147(2021), art. No. 111541.

[17]	Zhao Y, Ma YZ, Zhou RYet al.. Highly sensitive electrochemical detection of paraoxon ethyl in water and fruit samples based on defect-engineered graphene nanoribbons modified electrode. J. Food Meas. Charact., 2022, 1642596

[18]	Balandin AA. Thermal properties of graphene and nanostructured carbon materials. Nat. Mater., 2011, 108569

[19]	Shin SE, Choi HJ, Shin JH, Bae DH. Strengthening behavior of few-layered graphene/aluminum composites. Carbon, 2015, 82: 143

[20]	Q.M. Shi, R. Mertens, S. Dadbakhsh, G.C. Li, and S.F. Yang, In-situ formation of particle reinforced Aluminium matrix composites by laser powder bed fusion of Fe₂O₃/AlSi12 powder mixture using laser melting/remelting strategy, J. Mater. Process. Technol., 299(2022), art. No. 117357.

[21]	Lan T, Jiang YH, Zhang XJ, Cao F, Liang SH. Competitive precipitation behavior of hybrid reinforcements in copper matrix composites fabricated by powder metallurgy. Int. J. Miner. Metall. Mater., 2021, 2861090

[22]	X. Gao, X.Z. Kai, W. Qian, et al., Microstructure and mechanical property evolution of in situ ZrB₂/AA7085 nanocomposites during hot rolling, Mater. Charact., 195(2023), art. No. 112503.

[23]	C. Guan, G. Chen, X.Z. Kai, et al., Strengthening-toughening of graphene nanoplates and in situ ZrB₂ nanoparticles reinforced AA6111 matrix composites with discontinuous layered structures, Mater. Sci. Eng. A, 853(2022), art. No. 143750.

[24]	C. Guan, G. Chen, X.Z. Kai, et al., Transformation of dislocation strengthening mechanisms induced by graphene nanoplates and ZrB₂ nanoparticle in nanolaminated Al matrix composites, Mater. Charact., 199(2023), art. No. 112773.

[25]	Ren J, Zhang Y, Zhao DXet al.. Strong yet ductile nanolamellar high-entropy alloys by additive manufacturing. Nature, 2022, 608792162

[26]	Li H, Zong HX, Li SZet al.. Uniting tensile ductility with ultrahigh strength via composition undulation. Nature, 2022, 6047905273

[27]	Yang LZ, Pu BW, Zhang X, Sha JW, He CN, Zhao NQ. Manipulating mechanical properties of graphene/Al composites by an in situ synthesized hybrid reinforcement strategy. J. Mater. Sci. Technol., 2022, 123: 13

[28]	Y.H. Chao, J.Y. Pang, Y. Bai, et al., Graphene-like BN@SiO₂ nanocomposites as efficient sorbents for solid-phase extraction of Rhodamine B and Rhodamine 6G from food samples, Food Chem., 320(2020), art. No. 126666.

[29]	Jiao ZX, Wang QZ, Yin FXet al.. Novel laminated multilayer graphene/Cu–Al–Mn composites with ultrahigh damping capacity and superior tensile mechanical properties. Carbon, 2022, 188: 45

[30]	Feng SW, Guo Q, Li Zet al.. Strengthening and toughening mechanisms in graphene-Al nanolaminated composite micropillars. Acta Mater., 2017, 125: 98

[31]	Li Z, Fu XD, Guo Qet al.. Graphene quality dominated interface deformation behavior of graphene-metal composite: The defective is better. Int. J. Plast., 2018, 111: 253

[32]	C. Guan, Y.T. Zhao, G. Chen, et al., Synergistic strengthening and toughening of copper coated graphene nanoplates and in situ nanoparticles reinforced AA6111 composites, Mater. Sci. Eng. A, 822(2021), art. No. 141661.

[33]	K. Yun, J.M. Zhou, C.T. Zhao, X.M. Jiang, and L.H. Qi, Graphene reinforced magnesium metal matrix composites by infiltrating coated-graphene preform with melt, J. Mater. Process. Technol., 334(2024), art. No. 118639.

[34]	Z.Y. Liu, L.H. Wang, Y.N. Zan, et al., Enhancing strengthening efficiency of graphene nano-sheets in aluminum matrix composite by improving interface bonding, Composites Part B, 199(2020), art. No. 108268.

[35]	Gao HT, Liu XH, Qi JL, Ai ZR, Liu LZ. Microstructure and mechanical properties of Cu/Al/Cu clad strip processed by the powder-in-tube method. J. Mater. Process. Technol., 2018, 251: 1

[36]	Guo BS, Chen YQ, Wang ZWet al.. Enhancement of strength and ductility by interfacial nano-decoration in carbon nanotube/aluminum matrix composites. Carbon, 2020, 159: 201

[37]	Han TL, Liu EZ, Li JJ, Zhao NQ, He CN. A bottom-up strategy toward metal nano-particles modified graphene nanoplates for fabricating aluminum matrix composites and interface study. J. Mater. Sci. Technol., 2020, 46: 21

[38]	L.Y. Huang, X.Z. Kai, W. Qian, et al., Investigation on the high strength and improved creep behavior of in situ (Al₂O₃+ZrB₂)/7055 Al nanocomposites, Mater. Sci. Eng. A, 882(2023), art. No. 145467.

[39]	R. Cao, X.Z. Kai, W. Qian, T. Wang, Q. Peng, and Y.T. Zhao, Effect of in situ ZrB₂ nanoparticles on microstructure and mechanical properties of friction stir welding joints in 7N01 matrix composites, Mater. Charact., 207(2024), art. No. 113611.

[40]	Wang J, Li JJ, Weng GJ, Su Y. The effects of temperature and alignment state of nanofillers on the thermal conductivity of both metal and nonmetal based graphene nanocomposites. Acta Mater., 2020, 185: 461

[41]	T.L. Xu, S.S. Zhou, F. Jiang, N. Song, L.Y. Shi, and P. Ding, Polyamide composites with improved thermal conductivity for effective thermal management: The three-dimensional vertically aligned carbon network, Composites Part B, 224(2021), art. No. 109205.

[42]	Jiang XS, Liu WX, Li YJet al.. Microstructures and mechanical properties of Cu/Ti₃SiC₂/C/graphene nanocomposites prepared by vacuum hot-pressing sintering and hot isostatic pressing. Composites Part B, 2018, 141: 203

[43]	Goli P, Ning H, Li X, Lu CY, Novoselov KS, Balandin AA. Thermal properties of graphene–copper–graphene heterogeneous films. Nano Lett., 2014, 1431497

[44]	F. Lin, F.H. Jia, M.Y. Ren, et al., Microstructure, mechanical and thermal properties of ultrafine-grained Al2024–TiC–GNPs nanocomposite, Mater. Sci. Eng. A, 841(2022), art. No. 142855.

[45]	J.H. Jang, H.K. Park, J.H. Lee, J.W. Lim, and I.H. Oh, Effect of volume fraction and unidirectional orientation controlled graphite on thermal properties of graphite/copper composites, Composties Part B, 183(2020), art. No. 107735.

[46]	A.A. Tarhini and A.R. Tehrani-Bagha, Graphene-based polymer composite films with enhanced mechanical properties and ultra-high in-plane thermal conductivity, Compos. Sci. Technol., 184(2019), art. No. 107797.

[47]	R. Harichandran, R.V. Kumar, and M. Venkateswaran, Experimental and numerical evaluation of thermal conductivity of graphene nanoplatelets reinforced aluminium composites produced by powder metallurgy and hot extrusion technique, J. Alloy. Compd., 900(2022), art. No. 163401.

[48]	J.K. Tiwari, A. Mandal, N. Sathish, et al., Effect of graphene addition on thermal behavior of 3D printed graphene/AlSi10Mg composite, J. Alloy. Compd., 890(2022), art. No. 161725.

[49]	Wejrzanowski T, Grybczuk M, Chmielewski M, Pietrzak K, Kurzydlowski KJ, Strojny-Nedza A. Thermal conductivity of metal-graphene composites. Mater. Des., 2016, 99: 163

[50]	Z.M. Zhang, G.L. Fan, Z.Q. Tan, et al., Bioinspired multiscale Al₂O₃–rGO/Al laminated composites with superior mechanical properties, Composite Part B, 217(2021), art. No. 108916.

[51]	Cao HJ, Tan ZQ, Lu MHet al.. Graphene interlayer for enhanced interface thermal conductance in metal matrix composites: An approach beyond surface metallization and matrix alloying. Carbon, 2019, 150: 60