钛合金疲劳裂纹扩展速率Paris区中的转折点

通过对比钛合金不同显微组织下疲劳裂纹扩展速率Paris区转折点的位置,发现原始β晶粒尺寸是影响Paris区转折点位置的主要因素,晶团尺寸以及片层厚度对转折点位置没有影响.并且通过分析转折点前、后疲劳裂纹扩展微观阶段的转变及断裂方式变化,得出转折点的出现是疲劳裂纹尖端塑性区尺寸超过晶粒尺寸所致,具有β晶粒的马氏体组织疲劳裂纹扩展速率Paris区并不存在转折点,说明转折点的出现不仅仅是由于原始β晶粒的存在,还和显微组织类型有关.通过分析还发现,钛合金片层组织中裂纹尖端塑性区实际尺寸大于计算得到的单向塑性区尺寸以及循环塑性区尺寸.

川芎嗪甲酸对平滑肌细胞游离钙浓度的影响

目的:研究川芎嗪代谢产物川芎嗪甲酸(CTPZ)对大鼠阴茎海绵体平滑肌细胞(PCSMC)胞质内游离钙离子浓度的影响。方法:用新型Ca^(2+)荧光染色剂Fluo-3/AM负载大鼠PCSMC,细胞分为氯化钾(KCl)和去甲肾上腺素(NE)作用组,应用激光扫描共聚焦显微镜(LSCM)实时测定胞质内[Ca^(2+)]的变化,分别观察不同浓度的CTPZ对高钾和NE诱导胞质内钙浓度升高的影响,并与母药川芎嗪作用相比。结果:静息状态下,CTPZ对大鼠PCSMC胞质内[Ca^(2+)]无明显影响。1,10,100μmol·L^(-1)CTPZ能显著抑制高钾诱发的细胞内的钙浓度升高的影响,抑制率分别为(39.8±4.3)%,(49.2±3.6)%,(58.2±3.9)%。也能抑制1μmol·L^(-1)NE诱发钙库释放的细胞内[Ca^(2+)]升高,抑制率分别为(20.8±3.9)%,(32.3±2.5)%,(43.7±3.2)%。结论:CTPZ对大鼠PCSMC电压依赖性钙通道和细胞内钙库释放的抑制作用,能降低PCSMC胞质内[Ca^(2+)]水平,其作用效果比母药川芎嗪佳。

中温和高温煤沥青的组成结构与性质

深入分析了新疆哈密淖毛湖中温煤沥青(CTPZ)和陕西榆林高温煤沥青(CTPG)的元素组成、热稳定性、微晶结构、分子结构特征等,选用Flynn-Wall-Ozawa法计算其热解活化能,对其甲苯可溶物和热聚合后试样的甲苯可溶物进行了GC-MS分析。结果表明,CTPZ和CTPG的H/C原子比分别为1.005和0.510,O/C原子比分别为0.062和0.015;CTPZ的热解反应更加剧烈,轻组分逸出更快,热稳定性差,最终残炭率分别为16.03%和38.47%,CTPZ仅为CTPG的42%;在210~390℃,平均热解活化能分别为84.24和104.47 kJ/mol;芳香片层间距分别为0.404和0.356 nm,分别比石墨的芳香片层间距0.340 nm高出18.82%和4.71%,前者芳环上连有烷烃侧链和非平面结构的环烷烃更多,芳环层间有序性更差;CTPZ以正构长链烷烃为主,C20~C28相对含量超过50%,鉴于CTPZ正构烷烃的相对含量超过50%,且碳链长度在石蜡油的要求之内,故可分离制备石蜡油,而CTPG以芳烃为主,相对含量超过70%,其中,荧蒽类物质相对含量约达40%。热聚合结果表明,CTPG热聚合0.5 h,达到改质沥青一级品标准,宜做改质沥青原料,而CTPZ热聚合长达6 h,喹啉不溶物QI、结焦值CV和软化点SP等仍远离标准。经对热聚后试样进行GC-MS分析发现,CTPG中多环芳烃含量增加,表明其发生的是芳烃缩聚反应,而CTPZ中链状烷烃含量增加,表明其发生的是芳烃侧链部分的裂解反应。

Fatigue crack tip plastic zone ofα+βtitanium alloy with Widmanstatten microstructure

The recent studies had focused on the fatigue crack propagation behaviors of α＋β titanium alloys with Widmanstatten microstructure. The fascinated interest of this type of microstructure is due to the superior fatigue crack propagation resistance and fracture toughness as compared to other microstructures,which was believed to be related to the fatigue crack tip plastic zone（CTPZ）. In this study, the plastic deformation in fatigue CTPZ of Ti-6 A1-4 V titanium alloy with Widmanstatten microstructure was characterized by scanning electron microscope（SEM） and electron backscatter diffraction（EBSD）. The results showed that large-scale slipping and deformation twinning were generated in fatigue CTPZ due to the crystallographic feature of the Widmanstatten microstructure. The activation of twinning was related to the rank of Schmid factor（SF） and the diversity of twin variants developing behaviors reflected the influence of SF rank. The sizes of CTPZ under different stress intensity factors（K） were examined by the white-light coherence method, and the results revealed that the range of the plastic zone is enlarged with the increasing K（or crack length）, while the plastic strain decreased rapidly with the increasing distance from the crack surface. The large-scale slipping and deformation twinning in Widmannstatten microstructure remarkably expanded the range of fatigue CTPZ, which would lead to the obvious larger size of the observed CTPZ than that of the theoretically calculated size.