Tungsten carbide–cobalt (WC–Co) is prized for its hardness, but that same property makes it unusually difficult to shape. The current process is wasteful and expensive for the yield produced, and an economically sensible method for creating these materials is long overdue.

WC-Co cemented carbides are important in fields that require high wear resistance and hardness, such as cutting and construction tools. Currently, these carbides are made using powder metallurgy, utilizing high pressure and sintering machines to combine the WC and Co powders to yield a manufactured cemented carbide.

Though this method does produce highly durable and hard final products, a lot of expensive material is used, and the yield is suboptimal.

Next-generation technology requires next-generation materials that can be tailored to exact mission requirements. Additive manufacturing, or 3D printing, has already revolutionized industries like aerospace engineering by enabling previously unthinkable component designs. However, this technique has been largely limited to pre-existing metallic alloys. This is due to the inherent complexity of the process that leads to far-from-equilibrium microstructures and results in mechanical properties that are hard to predict.

New research on alloy microstructures

In a new study, scientists at Lawrence Livermore National Laboratory and their collaborators demonstrate a method to overcome the challenges of the traditional additive manufacturing process. By adjusting the speed of the laser in a compositionally complex alloy (also called high-entropy alloy), the team discovered a method to guide how the atoms settle as the metal solidifies, controlling the material’s properties directly at the atomic scale.