用量子力学研究膦化三氢化铝储氢材料在磷化氢催化作用下的释氢反应机理

利用量子力学第一原理研究了储氢材料膦化三氢化铝(AlH3PH3)在催化剂膦(PH3)作用下的释氢反应机理;首先在MP2/aug-cc-pVDZ水平上计算了反应物、过渡态和产物的几何构型和频率,进而利用内禀反应坐标理论确定了反应的最小能量路径,随后在CCSD(T)/aug-cc-pVDZ水平上对基于MP2优化的几何构型进行了能量校正.结果表明,AlH3PH3释氢的能垒高于Al―P键的离解能,而催化剂PH3不能降低AlH3PH3的释氢能垒.因此,需要寻找其他的催化剂以使AlH3PH3成为一种合用的储氢材料.     

硫辛酸抗氧化性溶剂效应的理论研究

采用密度泛函方法,利用自洽反应场(SCRF)的Onsager模型,研究了正庚烷、苯、二氯甲烷、乙醇、二甲亚砜和水六种不同溶剂中硫辛酸分子的抗氧化性。以S-S键键解离焓(BDE)和分子电离势(IP)为理论指标评价了硫辛酸在六种溶剂中清除自由基的活性。发现随着溶剂的介电常数增大,BDE值几乎不变,而IP值则显著减小,表明溶剂效应对清除自由基的电子转移反应机理影响更大。溶剂的极性较小时,偏向于形成硫自由基的机理,而溶剂的极性较大时,偏向于电子转移机理。     

ZSM-5高硅分子筛硅烷化疏水改性的研究

以甲苯为溶剂,正辛基三乙氧基硅烷(OTS)为改性剂,进行了ZSM-5高硅分子筛疏水改性研究。通过傅立叶红外(FT-IR)、X射线粉末衍射(XRD)、N2吸附-解吸附、静态水接触角、水与正己烷的静态吸附,以及水热稳定性试验等测试了改性前后样品结构与性能。结果表明,通过硅烷化改性在ZSM-5上接枝了-Si(CH2)7CH3基团,并实现了超疏水性。当0.8g ZSM-5使用0.24g改性剂时,改性后分子筛的接触角达152°,水吸附量下降了1.49%,比表面积、孔容、孔径分别减小了62.7m2/g、0.0329cm3/g、0.42nm,孔道长程有序性有所降低,且具有较高的水热稳定性。     

顶空气相色谱法测定瑞替加滨原料药中残留溶剂

建立了测定瑞替加滨原料药中残留溶剂乙醇、正己烷、四氢呋喃、三乙胺的顶空气相色谱方法。采用氢火焰离子化检测器,以N,N-二甲基甲酰胺为样品溶剂,通过对色谱条件优化,建立了以DB-624为分析柱、110℃为平衡温度、15 min为平衡时间的残留溶剂测定方法。经方法学验证,上述4种溶剂的方法检出限依次为0.007 5%、0.000 48%、0.002 4%、0.01%;峰面积的相对标准偏差均小于2.1%;平均回收率为100%～102%;4种溶剂的线性系数均大于0.995。结果表明,该方法的检测灵敏度高、精密度好、准确度高、线性关系良好,能够满足对瑞替加滨质量的控制要求。将该方法应用于3批瑞替加滨原料药的残留溶剂检测,均只检出乙醇和正己烷,且乙醇和正己烷的最高残留量分别为0.149%和0.022%,均未超出限量规定。     

澳洲茄胺单糖苷的合成及其抗肿瘤活性

以单糖为原料,经苯甲酰化保护和溴代制备中间体酰化溴代糖(3a～3e)。通过Koenigs-Knorr合成法将3a～3e与澳洲茄胺甙化缩合并脱保护合成了5个澳洲茄胺单糖苷化合物(5a～5e,5d和5e为新化合物),其结构经1H NMR,13C NMR和MS表征。用MTT法对5a～5e进行体外抗肿瘤细胞活性试验结果表明,5c和5d显示了较好的抗肿瘤活性。     

含环糊精链节的拓扑高分子

星形、超支化、树枝状、刷状等具有支化拓扑结构的高分子通常具有不同于直链结构高分子的优异性能。将有客体包合功能的环糊精与其结合构筑环糊精拓扑高分子体系,有望在分子识别、基因传输、药控释放等领域得到应用。本文根据高分子拓扑形态的不同,从星形、超支化、树枝状以及其他拓扑形态环糊精聚合物的合成及自组装构筑等方面进行了总结和评述,并在此基础上展望了基于环糊精的拓扑高分子的研究方向和发展趋势。     

绿色合成CdSe及制备CdSe-聚氨酯纳米复合发光材料

通过一步法绿色合成了CdSe-聚氨酯(CdSe-PU)纳米复合发光材料.在N2保护下,将单质硒(Se)溶于蓖麻油,以蓖麻油酸作为氧化镉(CdO)的配体,合成硒化镉(CdSe)纳米晶.将聚丙二醇2000和异佛尔酮二异氰酸酯(IPDI)合成的预聚体,加入含CdSe纳米晶的蓖麻油溶液,通过交联作用得到CdSe-PU纳米复合发光材料.采用紫外-可见分光光度计(UV-Vis)、荧光光谱仪(PL)、傅里叶红外光谱仪(FT-IR)、热重分析仪(TGA)、透射电子显微镜(TEM)对CdSe纳米晶和聚氨酯复合材料的结构和性能进行了表征.结果表明:此方法合成的CdSe纳米晶性能良好,能在聚氨酯纳米复合材料中均匀分散且性能稳定,CdSe-PU纳米复合材料耐热性有所提高.     

Ion Pairing Kinetics Does not Necessarily Follow the Eigen-Tamm Mechanism

The most recognized and employed model of the solvation equilibration in the ionic solutions was proposed by Eigen and Tamm, in which there are four major states for an ion pair in the solution： the completely solvated state, 2SIP （double solvent separate ion pair）, SIP （single solvent separate ion pair）, and CIP （contact ion pair）. Eigen and Tamm suggested that the transition from SIP to CIP is always the slowest step during the whole pairing process, due to a high free energy barrier between these two states. We carried out a series of potential of mean force calculations to study the pairing free energy profiles of two sets of model mono- atomic 1：1 ion pairs 2.0：x and x：2.0. For 2.0：x pairs the free energy barrier between the SIP and CIP states is largely reduced due to the salvation shell water structure. For these pairs the SIP to CIP transition is thus not the slowest step in the ion pair formation course. This is a deviation from the Eigen-Tamm model.     

Theoretical Insights into Intermolecular Hydrogen-Bonding Strengthening in Fluorenone-Methanol Complexes Induced by Electronic Excitation and Bulk Solvent Effect

This work presents a theoretical insight into the variation of the site-specific intermolecular hydrogen-bonding （HB）, formed between C=O group of fluorenone （FN） and O-H groups of methanol （MeOL） molecules, induced by both the electronic excitation and the bulk solvent effect. Through the calculation of molecular ground- and excited-state properties, we not only demonstrate the characters of HB strengthening induced by electronic excitation and the bulk solvent effect but also reveal the underlying physical mechanism which leads to the HB variation. The strengthening of the intermolecular HB in electronically excited states and in liquid solution is characterized by the reduced HB bond-lengths and the red-shift IR spectra accompanied by the increasing intensities of IR absorption corresponding to the characteristic vibrational modes of the O-H and C--O stretching. The HB strengthening in the excited electronic states and in solution mainly arises from the charge redistribution of the FN molecule induced by the electronic excitation and bulk solvent instead of the intermolecular charge transfer. The charge redistribution of the solute molecule increases the partial dipole moment of FN molecule and the FN-MeOL intermolecular interaction, which subsequently leads to the HB strengthening. With the bulk solvent effect getting involved, the theoretical IR spectra of HBed FN-MeOL complexes agree much better with the experiments than those of gas-phase FN-MeOL dimer. All the calculations are carried out based on our developed analytical approaches for the first and second energy derivatives of excited electronic state within the time-dependent density functional theory.     

DFT Study on Homolytic Dissociation Enthalpies of C-I Bonds

The C-I bond dissociation enthalpies （BDE） of various organic iodides were calculated using high-level theoretical methods including MP2 and CCSD（T） with extrapolated basis set as well as a number of density functional theory methods. After systematic evaluation of the theoretical results against available experimental C-I BDEs, it was found that the MPW LYPIM method gave the lowest root mean square error. We, therefore, used this method to examine the substituent effects on different categories of C（sp3）-I and C（sp2）-I bonds. Fur thermore, the remote substituent effects on the C-I BDEs of substituted iodobenzenes and substituted （iodomethyl）benzenes were also investigated at the same level. The C-I BDEs of typical heteroaromatic iodides including five-membered and six-membered heterocyclic iodides were also examined.