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martensitic transformation of biomedical Co-Cr-Mo alloys by introducing parent phase lattice defects森 真奈美*; 山中 謙太*; 佐藤 茂男*; 椿 真貴*; 佐藤 こずえ*; 熊谷 正芳*; 今福 宗行*; 菖蒲 敬久; 千葉 明彦*
Journal of the Mechanical Behavior of Biomedical Materials, 90, p.523 - 529, 2019/02
被引用回数:19 パーセンタイル:71.16(Engineering, Biomedical)In this study, we examined the effect of pre-existing dislocation structures in a face-centered cubic gamma-phase on strain-induced martensitic transformation (SIMT) to produce a hexagonal close-packed epsilon-phase in a hot-rolled biomedical Co-Cr-Mo alloy. The as-rolled microstructure was characterized by numerous dislocations as well as stacking faults and deformation twins. SIMT occurred just after macroscopic yielding in tensile deformation. Using synchrotron X-ray diffraction line-profile analysis, we successfully captured the nucleation of epsilon-martensite during tensile deformation in terms of structural evolution in the surrounding gamma-matrix: many dislocations that were introduced into the gamma-matrix during the hot-rolling process were consumed to produce epsilon-martensite, together with strong interactions between dislocations in the gamma-matrix. As a result, the SIMT behavior during tensile deformation was accelerated through the consumption of these lattice defects, and the nucleation sites for the SIMT epsilon-phase transformed into intergranular regions upon hot rolling. Consequently, the hot-rolled Co-Cr-Mo alloy simultaneously exhibited an enhanced strain hardening and a high yield strength. The results of this study suggest the possibility of a novel approach for controlling the to SIMT behavior, and ultimately, the performance of the alloy in service by manipulating the initial dislocation structures.
佐藤 成男*; 黒田 あす美*; 佐藤 こずえ*; 熊谷 正芳*; Harjo, S.; 友田 陽*; 齋藤 洋一*; 轟 秀和*; 小貫 祐介*; 鈴木 茂*
鉄と鋼, 104(4), p.201 - 207, 2018/00
被引用回数:9 パーセンタイル:44.29(Metallurgy & Metallurgical Engineering)To investigate the characteristics of dislocation evolution in ferritic and austenitic stainless steels under tensile deformation, neutron diffraction line-profile analysis was carried out. The austenitic steel exhibited higher work hardening than the ferritic steel. The difference in the work hardening ability between the two steels was explained with the dislocation density estimated by the line-profile analysis. The higher dislocation density of the austenitic steel would originate from its lower stacking fault energy. Dislocation arrangement parameters indicated that the strength of interaction between dislocations in the austenitic steel was stronger than that in the ferritic steel.
佐藤 成男*; 菖蒲 敬久; 佐藤 こずえ*; 小川 博美*; 我妻 一昭*; 熊谷 正芳*; 今福 宗行*; 田代 仁*; 鈴木 茂*
ISIJ International, 55(7), p.1432 - 1438, 2015/07
被引用回数:13 パーセンタイル:53.92(Metallurgy & Metallurgical Engineering)冷間延伸されたパーライト鋼ワイヤにおける転位の分布および異方性を特徴付けるために、X線回折線プロファイル解析をシンクロトロン放射マイクロビームを用いて行った。一般に、塑性せん断ひずみはワイヤの中心よりも表面近くでより激しかったが、中心から表面まで転位密度分布はほぼ一定であった。一方、転位の再配列は、転位の細胞構造を進化させ、表面に近づくほど進んだ。異方性転位密度によって、軸方向および横断方向の硬さの差異が説明できることも明らかになった。高温での回折データに基づく線プロファイル解析を行った。セメンタイトの回収率は一定の速度で進行したが、フェライト相の回収率は温度依存性を示し、フェライト相の回収率はセメンタイト相の回収率とはあまり関係していなかった。
