Mechanisms of radiation-induced segregation in CrFeCoNi-based single-phase concentrated solid solution alloys

Single-phase concentrated solid solution alloys have attracted wide interest due to their superior mechanical properties and enhanced radiation tolerance, which make them promising candidates for the structural applications in next-generation nuclear reactors. However, little has been understood abo...

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Veröffentlicht in:	Acta materialia 2016-12, Vol.126
Hauptverfasser:	He, Mo-Rigen, Wang, Shuai, Shi, Shi, Jin, Ke, Bei, Hongbin, Yasuda, Kazuhiro, Matsumura, Syo, Higashida, Kenji, Robertson, Ian M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Electron microscopy Irradiated metals MATERIALS SCIENCE Phase transformation Segregation Single-phase concentrated solid solution alloys
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container_title	Acta materialia
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creator	He, Mo-Rigen Wang, Shuai Shi, Shi Jin, Ke Bei, Hongbin Yasuda, Kazuhiro Matsumura, Syo Higashida, Kenji Robertson, Ian M.
description	Single-phase concentrated solid solution alloys have attracted wide interest due to their superior mechanical properties and enhanced radiation tolerance, which make them promising candidates for the structural applications in next-generation nuclear reactors. However, little has been understood about the intrinsic stability of their as-synthesized, high-entropy configurations against radiation damage. In this paper, we report the element segregation in CrFeCoNi, CrFeCoNiMn, and CrFeCoNiPd equiatomic alloys when subjected to 1250 kV electron irradiations at 400 °C up to a damage level of 1 displacement per atom. Cr/Fe/Mn/Pd can deplete and Co/Ni can accumulate at radiation-induced dislocation loops, while the actively segregating elements are alloy-specific. Moreover, electron-irradiated matrix of CrFeCoNiMn and CrFeCoNiPd shows L10 (NiMn)-type ordering decomposition and -oriented spinodal decomposition between Co/Ni and Pd, respectively. Finally, these findings are rationalized based on the atomic size difference and enthalpy of mixing between the alloying elements, and identify a new important requirement to the design of radiation-tolerant alloys through modification of the composition.
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Moreover, electron-irradiated matrix of CrFeCoNiMn and CrFeCoNiPd shows L10 (NiMn)-type ordering decomposition and -oriented spinodal decomposition between Co/Ni and Pd, respectively. 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title	Mechanisms of radiation-induced segregation in CrFeCoNi-based single-phase concentrated solid solution alloys
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