[1] Kuleshova E A, Gurovich B A, Shtrombakh Y I. Microstructural behavior of VVER-440 reactor pressure vessel steels under irradiation to neutron fluences beyond the design operation period [J]. Journal of Nuclear Materials, 2005, 342: 77-89.[2] Odette G R. On the dominant mechanism of irradiation embrittlement of reactor pressure vessel steels [J]. Scripta Metallurgica, 1983, 2: 1183-1188.[3] Akamatsu M, Van Duysen J C, Auger P. Experimental evidence of several contributions to the radiation damage in ferritic alloys [J]. Journal of Nuclear Materials, 1995, 225: 192-195.[4] Kameda J, Nishiyama Y. Combined effects of phosphorus segregation and partial intergranular fracture on the ductile-brittle transition temperature in structuralalloy steels [J]. Materials Science and Engineering A, 2011, 528: 3705-3713.[5] Miller M K, Sokolov M A. APT characterization of high nickel RPV steels [J]. Journal of Nuclear Materials, 2006, 351: 187-196.[6] Auger P, Pareige P. Synthesis of atom probe experiments on irradiation-induced solute segregation in French ferritic pressure vessel steels [J]. Journal of NuclearMaterials, 2000, 280: 331-344.[7] Lu Z, Faulkner R G, Flewitt P E J. The role of irradiation-induced phosphorus segregation in theductile-to-brittle transition temperature in ferritic steels [J]. Materials Science and Engineering, 2006, 437: 306-312.[8] Nishiyama Y, Onizawa K. Effects of neutronirradiation-induced intergranular phosphorus segregation and hardening on embrittlement in reactor pressurevessel steels [J]. Acta Materialia, 2008, 56: 4510-4521.[9] Gurovich B A, Kuleshova E A. Intergranular and intragranular phosphorus segregation in Russian pressure vessel steels due to neutron irradiation [J]. Journal of Nuclear Materials, 2000, 279: 259-272.[10] Lundin L, Richar B. Atom-probe study of phosphorus segregation to the carbide/matrix interface in an aged 9% chromium steel [J]. Applied Surface Science, 1995,88: 194-199.[11] Chang L, Smith G D W. The silicon effect in the tempering of Martensitic in steels [J]. J de Physique, 1984, 45: 397.[12] 刘文庆, 周邦新. 场离子显微镜和原子探针[M]// 中国机械工程学会, 中国材料研究学会. 中国材料工程大典. 北京: 化学工业出版社, 2006: 1045-1052.[13] 朱娟娟, 王伟, 林民东, 等. 用三维原子探针研究压力容器模拟钢中富Cu原子团簇的析出[J]. 上海大学学报: 自然科学版, 2008, 14(5): 526-527.[14] 王均安, 贺英, 邱振伟, 等. 小形变量轧制下电工钢中立方织构的形成[J]. 上海大学学报: 自然科学版, 2008, 14(5):463-465.[15] Gibbs JW. The collected works of J. Willard Gibbs [M]. New Haven: Yale University Press, 1948: 135-136. [16] F¨arber B, Cadel E. Phosphorus segregation in nanocrystalline Ni-3.6 at.%P alloy investigated with the tomographic atom probe (TAP) [J]. Acta Materialia,2000, 48: 791-793.[17] Miller M K, Russell K F. APFIM characterization of a high phosphorus Russian RPV weld [J]. Applied Surface Science, 1996, 94: 378-381.[18] Mclean D. Grain boundaries in metals [M]. London: Oxford University Press, 1957: 118.[19] 林文松. 微量溶质元素在金属晶界的偏聚[J]. 热处理, 2004, 19(2): 18-21.[20] Xu T. Critical time in temper embrittlement isotherms of phosphorus in steels [J]. Journal of Materials Science, 1999, 34(13): 3177.[21] Babu S S, Hono K, Sakurai T. APFIM studies on martensite tempering of Fe-C-Si-Mn low alloy steel [J]. Applied Surface Science, 1993, 67: 320-321.[22] Doane D V, Kirkaldy J S. Hardenablity concepts with applications to steels [M]. New York: Metallurgical Society of AIME, 1978: 249.[23] Mcmahon C J. Solute segregation and intergranular fracture in steels: a status report [J]. Materials Science and Engineering, 1980, 42: 215. |