Researchers Find a Way to 3D Print One of Industry's Hardest Engineering Materials

The manufacturing of WC‑Co cemented carbides has long relied on powder metallurgy, a process that demands high pressures, sintering cycles, and results in significant material loss. These ultra‑hard alloys are essential for cutting, drilling, and wear‑resistant applications, yet their production costs are driven up by expensive tungsten and cobalt powders and low yields. As industries push for greener, more efficient supply chains, the need for a less wasteful fabrication method has become a strategic priority.

The Hiroshima University team tackled this challenge by integrating hot‑wire laser irradiation into additive manufacturing. By pre‑heating a filler wire and directing a laser beam, the technique softens the WC‑Co blend just enough to bond layers without complete melting, preserving the microstructure that grants hardness. Introducing a nickel‑based alloy interlayer further stabilizes the temperature window, preventing WC decomposition and enabling a defect‑free build with hardness exceeding 1400 HV. Compared with traditional routes, the method deposits material only where needed, slashing raw‑material consumption and reducing energy use.

Beyond immediate cost savings, this approach opens new design possibilities for complex tool geometries that were previously impractical with conventional casting or sintering. The softening‑based AM process could be adapted to other superhard systems, such as TiC‑based composites or boron nitride ceramics, expanding its impact across aerospace, automotive, and mining sectors. Continued research will focus on scaling the process, mitigating residual cracking, and validating long‑term durability, positioning additive manufacturing as a viable pathway for next‑generation hard‑material production.