合肥工业大学主页平台管理系统 wang jing--Home-- Irradiation effects on binary tungsten alloys at elevated temperatures: Vacancy cluster formation, precipitation of alloying elements and irradiation hardening

汪京

Associate researcher

Supervisor of Doctorate Candidates

Supervisor of Master's Candidates

Date of Birth:1991-04-13

Date of Employment:2021-10-11

School/Department:合肥工业大学

Education Level:With Certificate of Graduation for Doctorate Study

Gender:Male

Degree:Doctoral degree

Status:Employed

Alma Mater:中国科学技术大学

Discipline:Other specialties in Material Science and Engineering
Material Process Engineering
Material Science
Material Physics and Chemistry

Recommended Ph.D.Supervisor Recommended MA Supervisor Team Member

Paper Publications

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Irradiation effects on binary tungsten alloys at elevated temperatures: Vacancy cluster formation, precipitation of alloying elements and irradiation hardening

Release time:2023-10-19 Hits:

Journal:Materials & Design

Key Words:Tungsten, Binary tungsten alloys, Atom probe tomography, Positron lifetime, Nanoindentation.

Abstract:Irradiation responses of binary W alloys were investigated systematically from the perspective of the binding energy of an alloying element with a W self-interstitial atom (W-SIA). Plates of W, W-0.3 at.% Cr, W-5 at.% Re, W-2.5 at.% Mo and W-5 at.% Ta alloys were irradiated at 1073 K with 6.4 MeV Fe ions to 0.26 dpa at the damage peak, where the binding energy of alloying element with W-SIA is in order of Cr > Re > Mo > Ta. The formation of vacancy-type defects (vacancies and vacancy clusters) was studied by using positron lifetime measurement. The precipitation of alloying elements was studied by using atom probe tomography (APT) and the hardness changes in the irradiated volumes were measured by the nanoindentation technique. The formation of vacancy-type defects was strongly suppressed by the addition of Cr and Re, while Ta and Mo had no noticeable suppression effect. The APT measurements showed fine Cr- and Re-rich precipitates in W-0.3 at.% Cr and W-5 at.% Re alloys, respectively, where the density of precipitates in the latter was clearly lower than that in the former. The distributions of Mo and Ta were uniform even after irradiation. Irradiation hardening was observed for all materials but that of W-5 at.% Re alloy was significantly smaller than the hardening of W, W-2.5 at.% Mo and W-5 at.% Ta alloys. These observations suggest that the irradiation hardening of W, W-2.5 at.% Mo, and W-5 at.% Ta alloys were mainly caused by vacancy-type defects. It was concluded that an alloying element with moderate binding energy with a W-SIA effectively suppresses vacancy formation without significantly enhanced precipitation and consequently mitigates irradiation hardening.

First Author:Jing Wang

Indexed by:Journal paper

Correspondence Author:Yuji Hatano

Document Code:111899

Discipline:Engineering

Issue:229

Translation or Not:no

Date of Publication:2023-04-06

Included Journals:SCI

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