Enhancing mechanical properties of ultrafine-grained tungsten for fusion applications

Tungsten, while showing many favorable properties, faces challenges in high-performance applications due to its brittle nature. One strategy to improve strength and toughness in tungsten is to refine the grain size down to the ultra-fine grained (ufg) regime. However, as the grain size is reduced, the fraction of grain boundaries that provide easy paths for crack growth increases, thereby limiting the gain in ductility. Therefore, strengthening the grain boundaries is of great importance if one wants to tap the full potential of this material. Using ab-initio calculations, potential grain boundary cohesion enhancing doping elements were identified, and doped ultra -fine grained tungsten samples were fabricated from powders and characterized extensively using small-scale testing techniques. We found that additions of boron and hafnium improve the mechanical properties of tung-sten remarkably. Furthermore, an additional low-temperature heat treatment of the boron-doped sample pro-motes grain boundary segregation, enhancing the properties even further. Thus, in this work we provide an effective pathway of improving mechanical properties in ultra-fine grained tungsten using grain boundary segregation engineering. This opens the door for many challenging applications of ufg W in harsh environments. To further underline the potential employment of ufg W in nuclear fusion reactors, a favorable swelling behavior and mechanical property response after irradiation with helium is presented within this work.

Automated summary

To improve the mechanical properties of tungsten, boron and hafnium were added to enhance the cohesion of grain boundaries. Small-scale testing techniques showed a significant improvement in the mechanical properties of tungsten after doping. Moreover, a low-temperature heat treatment of the boron-doped samples further enhanced the mechanical properties. This study provides an effective pathway for improving the mechanical properties of ultra-fine grained tungsten using grain boundary segregation engineering, enabling challenging applications in harsh environments.