Formation of intermetallic compound at interface between rare earth elements and ferritic-martensitic steel by fuel cladding chemical interaction 被引量：1

Formation of intermetallic compound at interface between rare earth elements and ferritic-martensitic steel by fuel cladding chemical interaction

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摘要 The intermetallic compounds formation at interface between rare earth elements and clad material were investigated to demonstrate the effects of rare earth elements on fuel-cladding chemical interaction （FCCI） behavior. Mischmetal （70Ce-30La） and Nd were prepared as rare earth elements. Diffusion couple testing was performed on the rare earth elements and cladding （9Cr2W steel） near the operation temperature of （sodium-cooled fast reactor） SFR fuel. The performance of a diffusion barrier consisting of Zr and V metallic foil against the rare earth elements was also evaluated. Our results showed that Ce and Nd in the rare earth elements and Fe in the clad material interdiffused and reacted to form intermetallic species according to the parabolic rate law, describing the migration of the rare earth element. The diffusion of Fe limited the reaction progress such that the entire process was governed by the cubic rate law. Rare earth materials could be used as a surrogate for high burnup metallic fuels, and the performance of the barrier material was demonstrated to be effective. The intermetallic compounds formation at interface between rare earth elements and clad material were investigated to demonstrate the effects of rare earth elements on fuel-cladding chemical interaction （FCCI） behavior. Mischmetal （70Ce-30La） and Nd were prepared as rare earth elements. Diffusion couple testing was performed on the rare earth elements and cladding （9Cr2W steel） near the operation temperature of （sodium-cooled fast reactor） SFR fuel. The performance of a diffusion barrier consisting of Zr and V metallic foil against the rare earth elements was also evaluated. Our results showed that Ce and Nd in the rare earth elements and Fe in the clad material interdiffused and reacted to form intermetallic species according to the parabolic rate law, describing the migration of the rare earth element. The diffusion of Fe limited the reaction progress such that the entire process was governed by the cubic rate law. Rare earth materials could be used as a surrogate for high burnup metallic fuels, and the performance of the barrier material was demonstrated to be effective.

作者 Jun Hwan Kim Byoung Oon Lee Chan Bock Lee Seung Hyun Jee Young Soo Yoon

机构地区 Advanced Fuel Development Division Department of Mate-rials Science and Engineering

出处《Journal of Rare Earths》 SCIE EI CAS CSCD 2012年第6期599-603,共5页 稀土学报（英文版）

基金 Project supported by National Nuclear Technology Program of National Research Foundation (NRF) Ministry of Education, Science and Technology (MEST), Korean Government

关键词 intermetallic compound sodium-cooled fast reactor （SFR） metallic fuel fuel-cladding chemical interaction （FCCI） rare earths BARRIER intermetallic compound sodium-cooled fast reactor （SFR） metallic fuel fuel-cladding chemical interaction （FCCI） rare earths Barrier

分类号 TG174.44 [金属学及工艺—金属表面处理]

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Journal of Rare Earths

2012年第6期

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Formation of intermetallic compound at interface between rare earth elements and ferritic-martensitic steel by fuel cladding chemical interaction 被引量：1

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