维格列汀相关物质的合成工艺改进

以盐酸金刚烷胺和L-脯氨酸为原料,经羟基化、氯乙酰化及氨基化反应合成了维格列汀相关物质(S)-1-［2-(3-羟基-金刚烷-1-氨基)-乙酰基］吡咯烷-2-羧酸（3）,其结构经¹H NMR, ¹³C NMR和MS（ESI）确证。采用Box-Behnken响应面法优化3的合成工艺。结果表明最优反应条件为：1-(2-氯乙酰基)吡咯烷-2-甲酸与3-氨基-1-金刚烷醇的摩尔比为2:1、三乙胺0.006 mol,于65 ℃反应4 h, 3的平均收率为82.84%,纯度98.8%,可作为维格列汀相关物质检测的对照品。     

3-羟基-1-金刚烷甲基酮的合成

改进了沙格列汀中间体3-羟基-1-金刚烷甲基酮（1）的合成路线。以金刚烷甲酸（2）为起始原料,经二氯亚砜酰氯化后与N-氯代琥珀酰亚胺（NCS)反应制得3-氯-1-金刚烷甲酰氯（3）; 3依次经取代,脱羧和与碱反应合成1,其结构经¹H NMR, IR和MS(ESI)确证。采用星点设计-效应面法对1合成条件进行了优化。结果表明:在最佳反应条件[2 28 mmol, n(NCS)/n(2)/n(AIBN)=1/0.83/0.65,于65 ℃反应8 h]下,1收率70%。     

Comparison of band structure and superconductivity in FeSe_(0.5)Te_(0.5) and FeS

The isovalent iron chalcogenides,FeSe_(0.5)Te_(0.5) and FeS,share similar lattice structures but behave very differently in superconducting properties.We study the underlying mechanism theoretically.By first principle calculations and tightbinding fitting,we find the spectral weight of the d_(X~2-Y~2) orbital changes remarkably in these compounds.While there are both electron and hole pockets in FeSe_(0.5)Te_(0.5) and Fe S,a small hole pocket with a mainly d_(X~2-Y~2) character is absent in FeS.We find the spectral weights of d_(X~2-Y~2) orbital change remarkably,which contribute to electron and hole pockets in FeSe_(0.5)Te_(0.5) but only to electron pockets in FeS.We then perform random-phase-approximation and unbiased singular-mode functional renormalization group calculations to investigate possible superconducting instabilities that may be triggered by electron-electron interactions on top of such bare band structures.For FeSe_(0.5)Te_(0.5) ,we find a fully gapped s~±-wave pairing that can be associated with spin fluctuations connecting electron and hole pockets.For Fe S,however,a nodal dxy(or d_(x~2-y~2) in an unfolded Broullin zone)is favorable and can be related to spin fluctuations connecting the electron pockets around the corner of the Brillouin zone.Apart from the difference in chacogenide elements,we propose the main source of the difference is from the d_(X~2-Y~2) orbital,which tunes the Fermi surface nesting vector and then influences the dominant pairing symmetry.     

内掺Sc原子的扩展三明治结构graphene-Sc-graphene的几何结构,电子性质和储氢性能研究

使用密度泛函理论中的广义梯度近似对内掺Sc原子的graphene-Sc-graphene扩展三明治结构的几何结构、电子结构和储氢性能进行计算研究. 计算发现: Sc原子位于单层石墨烯中六元环上方的结构具有较大的结合能, 但小于固体Sc的内聚能实验值(3.90 eV), 然而, 当单个Sc原子或者多个Sc原子在双层石墨烯中间与底层相距2 Å时, Sc原子与基底的结合能增加到5 eV以上, 远远大于固体Sc的内聚能实验值(3.90 eV), 因此相邻的Sc原子可以有效避免成簇. 由此可见, 三明治结构的形成明显增加了Sc原子与基底的结合强度, 该结构可以进一步储氢来满足18电子规则而更加稳定, 从而成为理想的新型储氢纳米材料. 扩展三明治结构graphene-Sc-graphene的(2×3)单元中每个Sc原子最多可以吸附2个H₂分子, 对H₂的平均吸附能分别为0.67 eV和0.54 eV, 介于物理吸附和化学吸附(0.1～0.8 eV)之间, 因此该体系可以实现常温常压下对H₂的可逆吸附. 由储氢机制分析可知: 扩展三明治结构graphene-Sc-graphene主要通过Dewar-Kubas作用进行储氢, 形成了π-δ-π型的电子结构.