Effect of bonding temperature on tensile behaviors and toughening mechanism of W/(Ti/Ta/Ti) multilayer composites

Effect of bonding temperature on tensile behaviors and toughening mechanism of W/(Ti/Ta/Ti) multilayer composites

The inherent low-temperature brittleness has restricted the application of tungsten materials. One option for enhancing the tungsten fracture toughness is to use tungsten-based layered composites. In this study, W/(Ti/Ta/Ti) multilayer composites with the application of spark plasma sintering under...

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Bibliographic Details
Main Authors: Liu Rui, Liu Houlong, Zhu Jie, Li Huan, Wu Jinping
Format: Article
Language:English
Published: De Gruyter 2025-04-01
Series:High Temperature Materials and Processes
Subjects:
tungsten
multilayer composites
tensile behaviors
toughening mechanism
ductile-to-brittle transition temperature
Online Access:https://doi.org/10.1515/htmp-2025-0075
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Summary:The inherent low-temperature brittleness has restricted the application of tungsten materials. One option for enhancing the tungsten fracture toughness is to use tungsten-based layered composites. In this study, W/(Ti/Ta/Ti) multilayer composites with the application of spark plasma sintering under varying bonding temperatures from 1,000 to 1,400°C were fabricated. The ambient- and high-temperature tensile mechanical performance of W/(Ti/Ta/Ti) samples is investigated to obtain the correspondence of microstructure to tensile performance. The as-fabricated composites exhibit significantly superior comprehensive tensile performance to the original foil. When bonded at 1,200°C, the comprehensive tensile performance of W/(Ti/Ta/Ti) samples is the best, showing an elongation of 5.0% and a tensile strength of 671 MPa. The bonding temperature leads to microstructural changes in the as-fabricated composites, thereby affecting their high-temperature tensile mechanical properties. When bonded at 1,000°C, the ductile–brittle transition temperature (DBTT) is approximately 100°C. When bonded at 1,200°C, the DBTT is approximately between 100 and 200°C. When bonded at 1,400°C, the DBTT is between 100 and 200°C. For W/(Ti/Ta/Ti) multilayer composites having low interfacial bonding strength, the primary energy dissipation modes include intermediate-layer plastic deformation, multi-tunnel crack propagation in the W layer, as well as W/Ti interfacial delamination. As for W/(Ti/Ta/Ti) multilayer composites having high interfacial bonding strength, energy can only be consumed through the principal crack propagation. Meanwhile, a tensile strength model is constructed based on the stress concentration coefficient after the nucleation of microcracks at the W/Ti interface.
ISSN:2191-0324

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