A flexible graphene-aluminum composite thermal strap with high thermal conductivity: two-step vacuum welding process optimization and interfacial microstructure control

The joining of graphene and metal to prepare a thermal strap is an effective method to enhance the heat dissipation capability of high heat-generating devices in spacecraft applications. A two-step vacuum welding method was employed to fabricate the flexible graphene-aluminum composite thermal strap. Firstly, multi sheets graphene films were brazed using AgCu4.5Ti filler metal, resulting in a typical interfacial microstructure characterized by AgCu4.5Ti/Cu(s,s) + Ag(s,s)/TiC/graphene. In addition, by studying the capillary filling behavior of AgCu4.5Ti between graphene films under various brazing temperatures and time, a reliable AgCu4.5Ti/graphene joint was obtained at 1123 K for 10 min. Secondly, the terminal Ni(P)-deposited 6061 aluminum alloy was soldered to the graphene films assembly brazed with AgCu4.5Ti using Sn63Pb37 solder. The interfacial microstructures of the Sn63Pb37/Ni(P)-deposited 6061 aluminum alloy joints transformed from Ni₃Sn₄+Ni₃P to Ni₂SnP + Ni₂P with increasing soldering temperature and further transformed to Ni₂SnP as the soldering time increased. The optimal soldering parameters were identified as 573 K for 10 min. Flexibility and thermal performance analyses demonstrated that the flexible graphene-aluminum composite thermal strap exhibited excellent flexibility and achieved a thermal conductivity of 1345.52 W m⁻¹ K⁻¹.