Highly thermal-conductive graphite flake/Cu composites prepared by sintering intermittently electroplated core-shell powders

doi:10.1016/j.jmst.2020.05.044

Abstract

Abstract:

Graphite flake/Cu composite has attracted tremendous attention as a promising heat sinks materials owing to its easy machinability and superior thermal properties. However, its preparation process still faces several technological limitations including complex, time-consuming and costly synthetic approaches. In this work, a facile and scalable intermittently electroplated method is applied to prepare Cu-coated graphite flake composite powders, which are subsequently sintered into dense composite bulks. The results show that the graphite flake is successfully coated with a uniform and compact Cu shell, which effectively inhibits the segregation accumulation of graphite flakes and contributes to homogeneous distribution of graphite in the sintered graphite flake/Cu composites. The as-sintered composites exhibit an excellent thermal conductivity of 710 W·m^-1·K^-1 and an outstanding bending strength of 93 MPa. Such performance, together with the simple, efficient powder-preparation process, suggests that the present strategy may open up opportunities for the development of thermal management materials.

Key words: Graphite flake, Electroplating, Powder processing, Thermal properties

Hong Sun, Nan Deng, Jianqiang Li, Gang He, Jiangtao Li. Highly thermal-conductive graphite flake/Cu composites prepared by sintering intermittently electroplated core-shell powders[J]. J. Mater. Sci. Technol., 2021, 61: 93-99.

Figures/Tables 7

Fig. 1. (a) Schematic illustration of the preparation of GF/Cu composites; SEM morphologies of (b) 40 vol%, (c) 60 vol%, (d) 90 vol% GF/Cu composite powders.

Fig. 2. XRD spectra of the GF/Cu composite bulks with varying GF volume fractions in the XY and Z directions: (a) 40 %, (b) 50 %, (c) 60 %, (d) 70 %, (e) 80 %, (f) 90 %.

Fig. 3. SEM morphology of the GF/Cu composite bulks with varying GF volume fractions in the XY direction: (a) 40 %, (b) 50 %, (c) 60 %, (d) 70 %, (e) 80 %, (f) 90 %.

Fig. 4. Fracture morphology of GF/Cu composite: (a) XY direction, (b) Z direction.

Fig. 5. TC of the GF/Cu composites: (a) XY plane, (b) Z direction.

Fig. 6. Comparison of the in-plane TC value of GF/Cu fabricated by different methods [30,31,[55], [56], [57]].

Fig. 7. The bending strength of GF/Cu composites with a varying volume fraction of GF.

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