Combinatorial Deposition of Ultrathick Ta-W-Au-Bi High-Entropy Alloys for Next-Generation Hohlraums by Direct-Current Magnetron Sputtering

D. C. Goodelman; A. M. Engwall-Holmes; G. V. Taylor; B. J. Bocklund; D. J. Strozzi; S. J. Shin; E. Kim; N. Vishnoi; S. O. Kucheyev; L. B. Bayu Aji

doi:dx.doi.org/10.1080/15361055.2025.2545591

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Combinatorial Deposition of Ultrathick Ta-W-Au-Bi High-Entropy Alloys for Next-Generation Hohlraums by Direct-Current Magnetron Sputtering

D. C. Goodelman, A. M. Engwall-Holmes, G. V. Taylor, B. J. Bocklund, D. J. Strozzi, S. J. Shin, E. Kim, N. Vishnoi, S. O. Kucheyev, L. B. Bayu Aji

Fusion Science and Technology / Volume 82 / Number 5 / July 2026 / Pages 1023-1033

Research Article / dx.doi.org/10.1080/15361055.2025.2545591

Received:December 5, 2024

Accepted:August 4, 2025

Published:June 15, 2026

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Hohlraum temperature calculations with the model by J. H. Hammer and M. D. Rosen predict a higher X-ray drive from Ta-W-Au-Bi high-entropy alloys compared to pure Au and recently developed Ta₄Au and Au-Bi hohlraums. Here, we study the microstructure and properties of µm-thick Ta-W-Au-Bi alloy films deposited via combinatorial direct-current magnetron sputtering. All of the films have promising physical properties, including high electrical resistivity, that satisfy the requirements for magnetically assisted inertial confinement fusion experiments. While porosity tends to increase with increasing Bi content, we also found that films with Bi content > 44 at. exhibited densification close to the substrate/film interface and formed a single-phase alloy. These findings provide a potential path forward for the development of Ta-W-Au-Bi alloys for next-generation hohlraum materials.