Micro-segregation model calculation of residual tin in boiler and pressure vessel steel

Tin is a typical residual element in steel and mainly originates from Sn-containing complex iron ore and steel scrap. The segregation of Sn in steel is harmful to the performances of steel. In this paper, the micro-segregation of residual element Sn during the solidification process of boiler and pressure vessel steel by micro-segregation model was studied. The results showed that the micro-segregation degree of Sn reduces apparently with the increase of cooling rate and remarkably deteriorates during the solidification process. When the initial content of C is higher than 0.1%, it will cause the solidification transform of the solid phase converting from the ferrite phase to austenite phase and the significant increase in the micro-segregation degree of Sn. However, increasing the initial contents of Si, Mn, P and S separately has non-significant effects on the micro-segregation degree of Sn. In addition, the improvement of initial content of Sn will lead to the micro-segregation degree decrease of Sn and has an inapparent impact on zero strength temperature and zero ductility temperature of the boiler and pressure vessel steel.     

不同拓扑构型嵌段液晶分子的合成与相变行为

本文对近来报道的三类嵌段液晶分子：多羟基1－苯甲酰胺－2,3－丙二醇两亲性分子I,星状季戊四醇苯甲酸酯II及带侧链的波拉化合物III的合成及自组装行为作了综述。这些分子由各向异性嵌段、两亲性嵌段和烷基链（或全氟链）以不同的拓扑形式组合而成,其合成的关键步骤是Pd(0)催化下碘代全氟烷烃对双键的自由基加成反应以及Pd(0)催化的偶合反应。通过调节亲水部分和亲脂部分的比例, 在I和II-F中观察到了从近晶层相（Sm）到柱相（Col）再到三维立方相（Cub）的液晶相序列;在波拉分子III-F中通过改变侧链的长度, 获得了一系列柱相及新型层相。这些研究表明, 利用多元化竞争组合理念,将分子中不相容的部分以不同的拓扑形式结合在一起,通过它们的微观相分离, 形成不同的微观区域, 获得不同的界面, 产生不同的界面曲率, 可设计合成具有不同微观结构的超分子体系, 从而在分子水平上控制分子的自组装行为; 同时全氟链的引入所带来的氟效应能促进微观分离,稳定液晶相,并有利于复杂超分子体系的产生。