Texture evolution and basic thermal–mechanical properties of pure tungsten under various rolling reductions

Basic thermal–mechanical properties and texture evolution of pure tungsten with various rolling reductions were characterized. The 60% rolled tungsten exhibited the highest thermal conductivity and the best Charpy impact performance, which can be attributed to its few pores and cracks simultaneously...

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Published in:Journal of nuclear materials 2016-01, Vol.468, p.339-347
Main Authors: Zhang, Xiaoxin, Yan, Qingzhi, Lang, Shaoting, Xia, Min, Ge, Changchun
Format: Article
Language:English
Subjects:
Evolution
Fibers
Nuclear engineering
Porosity
Reduction
Rolling reduction
Surface layer
Texture
Thermal-mechanical properties
Tungsten
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container_title Journal of nuclear materials
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description Basic thermal–mechanical properties and texture evolution of pure tungsten with various rolling reductions were characterized. The 60% rolled tungsten exhibited the highest thermal conductivity and the best Charpy impact performance, which can be attributed to its few pores and cracks simultaneously. Furthermore, full recrystallization was achieved on the rolled tungsten with 60% and 90% reduction after annealing at 2073K for 2h. More importantly, the 40%, 60%, 90% rolled tungsten displayed more γ fiber texture while 80% rolled tungsten exhibited more θ fiber texture and Goss texture. The rolled pure tungsten with 80% reduction may exhibit the best irradiation resistance. •60% rolled tungsten exhibited the highest thermal conductivity.•60% rolled tungsten exhibited the best Charpy impact performance.•40%, 60%, 90% rolled tungsten displayed more γ fiber texture.•80% rolled tungsten showed more θ fiber texture and Goss texture.•80% rolled tungsten may exhibit the best irradiation resistance.
doi_str_mv 10.1016/j.jnucmat.2015.04.001
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subjects Evolution
Fibers
Nuclear engineering
Porosity
Reduction
Rolling reduction
Surface layer
Texture
Thermal-mechanical properties
Tungsten
title Texture evolution and basic thermal–mechanical properties of pure tungsten under various rolling reductions
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