Progress in Industrialization of Tungsten Fiber-Reinforced Tungsten Composites

Journal article

Plasma-facing materials (PFMs) for future fusion reactors require advanced mechanical and thermal properties to withstand the extreme challenges of high heat flux, plasma exposure, and neutron irradiation. Tungsten is one of the most suitable materials for use as a PFM in the divertor region. However, considering the high thermal loading/thermal stress combining plasma exposure and neutron irradiation/embrittlement, one of the major concerns for tungsten in PFMs is its intrinsic brittleness. To avoid cracking and components failure, tungsten toughening has been widely investigated, including the development of tungsten fiber-reinforced tungsten composites (Wf/W) using an extrinsic toughening mechanism, which could provide damage resilience against neutron embrittlement. Recently, a type of aligned long-fiber Wf/W (L-Wf/W) based on a powder metallurgical fabrication process was developed, demonstrating advanced fracture toughness while retaining other application-relevant properties. For L-Wf/W, the relatively easy production process suggests the feasibility and basis of industrialization. This work reports on the initial progress in industrializing L-Wf/W, with a focus on adapting the lab sintering process to a sintering process with industrial partner (Dr. Fritsch Sondermaschinen GmbH) and optimizing the process parameters. To improve the sinterability of tungsten and achieve higher density, various tungsten powders were explored, including commercial W powders, bimodal mixtures of different particle sizes, and granulated W powders. At the dedicated yttria interface, the thickness of yttria coating on the fibers was also optimized to ensure effective separation between the fibers and the matrix. Series of samples were produced with different dimensions up to 100 mm × 100 mm × 4 mm. After optimization, samples with 93% density and desired pseudo-ductility were prepared. Similarly to production in the lab, a major challenge in this work involved balancing the densification of the tungsten matrix with controlling fiber recrystallization and mitigating damage to the yttria interface.

Authors: Mao, Y; Wilkinson, U; Coenen, JW; Wilkinson, D; Riesch, J

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: MDPI
• Journal: Journal of Nuclear Engineering
• Volume: 7
• Issue: 2
• Pages: 24
• Article number: 24
• Publication date: 2026-03-25
• Acceptance date: 2026-03-13
• DOI: 10.3390/jne7020024
• EISSN: 2673-4362
• ISSN: 2673-4362
• Language: English
• Keywords: field assisted sintering technology; pseudo ductility; plasma-facing materials; tungsten fiber-reinforced tungsten composites; production upscaling