一种含光亲和标记异戊烯侧链探针的合成与初步表征

经5步反应、以9%的总收率合成了一种含生物素修饰和光亲和标记的异戊烯侧链功能探针分子, 初步考察了反应条件下该探针分子与Saccharomyces cerevisiae AS 2.399粗蛋白的相互作用; 生物素印迹分析结果表明, 酵母中多种蛋白被探针分子修饰, 为进一步开展化学蛋白组学研究奠定了基础.     

小分子优先结晶构筑聚合物/非富勒烯共混体系互穿网络结构

非富勒烯小分子受体(SMAs)有序聚集决定聚合物/非富勒烯共混体系光伏电池的双分子复合几率。 然而,由于非对称相分离聚合物趋于优先形成网络,抑制小分子受体分子结晶。 在聚[(2,6-(4,8-二(5-(2-乙基己基噻吩-2-基)苯并[1,2-b:4,5-b']二噻吩))-alt-(5,5-(1',3'-二-2-噻吩基-5',7'-二(2-乙基己基)苯并[1',2'-c:4',5'-c']二噻吩-4,8-二酮))](PBDB-T)/9-二(2-亚甲基(3-(1,1-二氰基亚甲基)-6,7-二氟-茚酮))-5,5,11,11-四(4-己基苯基)-二噻吩并[2,3-d:2',3'-d']-s-引达省[1,2-b:5,6-b']二噻吩(IT-4F)共混体系,四氢呋喃蒸汽处理可提高IT-4F结晶性,150 ℃热退火可提高PBDB-T的结晶性。 因此,依次利用蒸汽退火和热退火处理薄膜,诱导小分子先结晶、聚合物后结晶,从而降低PBDB-T对小分子扩散的限制,构建高结晶互穿网络结构。 形貌优化后降低了双分子复合,器件光电转换效率从5.95%提高至7.18%。     

吡啶盐-氯胺前体的合成及在聚氨酯表面固载的抗菌应用

以5,5-二甲基海因为起始原料,经5步反应合成了携有全氟苯基叠氮基团(PFPA)的可固载型吡啶盐-氯胺前体,并在254 nm光照条件下分别将其固载到聚氨酯(PU)膜表面.经稀漂白水处理后,以大肠杆菌(ATCC 25922)和金黄色葡萄球菌(ATCC 25923)为测试菌种,测试了所得膜材料的抗菌活性.结果表明,改性PU膜有良好的抗菌性能,尤其PU表面接枝结构中含较短烷基链的前体时,抗菌活性更优.在制备非溶出型抗菌膜材料的同时也提供了一种惰性材料表面固载氯胺前体的普适方法.     

携异戊烯基光亲和化学探针的合成和应用

应用“一锅法”耦连反应为关键步骤合成了3个同时含有异戊烯链和叠氮基团的光亲和探针分子。在光照条件下这些化合物和酿酒酵母总蛋白反应后,经过点击反应与含有生物素的报告分子连接,再进行亲和素印迹分析,初步表明它们可作为钓取与异戊烯链相互作用蛋白的化学探针。     

Fluid-solid coupling model for studying wellbore instability in drilling of gas hydrate bearing sediments

As the oil or gas exploration and development activities in deep and ultra- deep waters become more and more, encountering gas hydrate bearing sediments （HBS） is almost inevitable. The variation in temperature and pressure can destabilize gas hydrate in nearby formation around the borehole, which may reduce the strength of the formation and result in wellbore instability. A non-isothermal, transient, two-phase, and fluid-solid coupling mathematical model is proposed to simulate the complex stability performance of a wellbore drilled in HBS. In the model, the phase transition of hydrate dissociation, the heat exchange between drilling fluid and formation, the change of mechanical and petrophysical properties, the gas-water two-phase seepage, and its interaction with rock deformation are considered. A finite element simulator is developed, and the impact of drilling mud on wellbore instability in HBS is simulated. Results indicate that the re- duction in pressure and the increase in temperature of the drilling fluid can accelerate hydrate decomposition and lead to mechanical properties getting worse tremendously. The cohesion decreases by 25% when the hydrate totally dissociates in HBS. This easily causes the wellbore instability accordingly. In the first two hours after the formation is drilled, the regions of hydrate dissociation and wellbore instability extend quickly. Then, with the soaking time of drilling fluid increasing, the regions enlarge little. Choosing the low temperature drilling fluid and increasing the drilling mud pressure appropriately can benefit the wellbore stability of HBS. The established model turns out to be an efficient tool in numerical studies of the hydrate dissociation behavior and wellbore stability of HBS.