分子极化效应指数与脂肪族醛酮的沸点

建立物质的定量结构—活性相关性(QSAR)和定量结构—性质相关性(QSPR)的研究一直受到化学工作者的关注。用拓扑指数研究饱和烃的各种物理化学性质已经有大量报道1 4。本文讨论了分子极化效应指数[5]与脂肪族醛酮沸点的关系,力求寻找到一个适用范围广,并且具有分子结构特征的计算脂肪族醛酮沸点的计算公式。1　分子结构参数的确定脂肪族醛酮分子中羰基的存在,使相同碳原子数的醛酮沸点比烷烃升高很多。我们以醛酮分子中的烷基极化效应指数(PEI)的差值(ΔPEI)[6]来表示羰基位置对醛酮沸点的影响:ΔPEI=PEIB,N-PEInrm,N(1)式中,…     

原子序数拓扑指数与脂肪族醛酮沸点的定量关系研究

按自定的编号规则,给醛酮分子中的碳原子和氧原子编号,并在此基础上建立新的拓扑指数(m^M),其中1^M对醛酮分子具有良好的结构选择性,并与72种醛酮的沸点显著相关：lg(660-Tbp)=5.8581-0.0111^M,γ=0.9970。引入0^M及其碳原子数的三元线性方程为：Log(679-Tbp)=6.045+0.0940^M-0.0201^M-0.194N,R=0.9991,明显优于文献的研究结果。并为预测脂肪族醛酮的沸点提供了有效的方法。     

有效碳链长度与脂肪醇的沸点

脂肪醇沸点(b.p.)变化规律可用下述关系式表示:ln(800.386-T~b)=6.64919-2.94828×10^-^2N~E~C~C+0.150955ΔPEI。式中N~E~C~C为醇中烷基的有效碳链长度, ΔPEI是具有相同碳原子数目的支链烷基与直链烷基的极化效应指数的差值, 它表示羟基对醇的沸点的影响。     

胺、醇和醚类化合物电离能的估算

脂肪族胺、醇、醚、硫醇和硫醚的第一电离能Ip与N、O、S原子的电负性X~Z^O、分子中N、O、S原子的部分电荷q~z以及烷基的极化效应指数PEI的关系可以表示为:Ip(eV)=4.4851+3.0727X~Z~O+7.1702q~z-1.3949∑PEI上式较好地表达了脂肪族胺、醇、醚、硫醇和硫醚的第一电离能变化的共同规律。     

诱导效应指数与脂肪族胺、醇和醚的气相碱性

用烷基诱导效应指数I和RX分子中质子亲合原子X所带电荷qx及元素电负性XN与 脂肪胺，醇、醚的气相质子亲合PA进行关联，结果表明，脂肪胺，醇、醚的气相碱 性可以用下式定量描述：PA(kJ.mol^-1)-2732.0333-2457.1510∑I-1492.2351qx- 732.6277XN利用上式对64种化合物的气相碱性进行预测，平均相对误差为0．34％ ，预测值和实验值的偏差均在实验误差范围内。     

脂肪族胺、醇和醚气相碱性的通用表达式

脂肪族胺、醇和醚气相质子亲合能(PA)与N、O原子所带电荷(qx)、烷基的极化效应指数(PEI)以及N、O原子的sp^3杂化轨道能量[Ex(sp^3)]的并系可以表示为：PA(kj/mol)=2383.5547-1060.3351qx+59.4247∑PEI-117.0142Ex(sp^3)。上式较好地表达了脂肪族胺、醇和醚气相碱性的共同规律。     

分子诱导效应指数与链烷烃的沸点

利用基团的诱导效应指数，首次提出了分子的诱导效应指数的概念，并定义了 链烷烃的有效碳链长度NC＝（MIs,N/MIb,N)·N，式中MIs,N,MIb,N分别为直链和支 链异构体的分子诱导效应指数。研究结果表明，链烷烃的沸点Tb(℃）与NC关系是 ：1n(806.5-Tb)=6.9824-0.11431NC^2/3     

脂肪族胺、醇、醚气相碱性的模型研究

以烷基极化效应指数(PEI)和分子中亲合原子的平衡电负性(XE)及亲合原子的Pauling电负性(X)为基本参数,研究了脂肪族胺、醇、醚的气相碱性(PA)的共同变化规律。结果表明,脂肪族胺、醇、醚的气相碱性可用下列通式来定量描述：PA(KJ/mol)=2468.6730+557.3172∑PEI-551.4261XE-1230.5770(∑PEI/XE)-111.5537X用上式预测了64种化合物的气相碱性,平均绝对相对误差仅为0.34%,预测值与文献值的偏差完全落在实验误差的范围内。     

季戊四醇双缩脂肪族醛(酮)螺环化合物的合成

以脂肪族醛(酮)为原料,对甲苯磺酸为催化剂,在环己烷中回流分水反应合成了一系列季戊四醇双缩脂肪族醛(酮)螺环化合物(3a~3l),其中3,9-二甲基-3,9-二丁基-2,4,8,10-四氧杂螺[5.5]十一烷(3i)和3,7,11,15,18,21-六氧杂三螺[5.2.2.512.29.26]二十一烷(3k)为新化合物,其结构经1H NMR,13C NMR和ESI-MS表征。     

药物离子选择性电极响应规律的系统研究——Ⅲ.红霉素电极及其对季铵的选择性规律

本文研究了多种红霉素电极。电极对于季铵的选择性可用诱导效应和空间位阻效应来定量说明,符合方程式logK_(ij)=a_1I-a_2Z/R+a_0,式中I为诱导效应指数,a_1,a_2,a_0为与电活性物有关的系数。建立了阳离子型药物电极K_(ij)对季铵烷基链碳原子数n的关系的一般数学模型:logK_(ij)=A/2.7~n+B/(0.80+1.26n)+C。证明:随着碳原子数增大,logK_(ij)趋于一极限值C。此处A,B,C为与电活性物有关的系数。     

分子连接性指数~mX~z与不饱和链烃沸点的定量关系研究

提出了一个计算分子中成键原子点价δ_i~z的新方法，以δ_i~z为基础建构的 新的分子连接性指数为~mX~z = ∑(δ_i~z·δ_j~z·δ_k~z……)~(-0.5)，其中 ~0X~z，~1X~z的定义为：~0X~z = ∑(δ_i~z)~(-0.5), ~1X~z = ∑(δ_i~z·δ _j~z)~(-0.5)，并研究了~0X~z,~1X~z与不饱和链烃沸点的相关性。结果表明，该 拓扑指数具有良好的结构-性质相关性。以~0X~z,~1X~z和碳原子数N为结构参数分 别与80个单烃烃、39个单炔烃、169个不饱和链烃（包括烷烃、炔烃及烯炔）的沸 点进行关联所得到的三元回归方程为：单烯烃，log(779.13-bp) = 2.822433-0. 0133346 ~0X~z - 0.0638379 ~1X~2 + 0.0111229N (R = 0.99895, F = 202783. 65, s = 3.36)；单炔烃，log(797.47-bp) = 2.809912-0.0108374~0X~z - 0. 0864540 ~1X~z + 0.0233028N (R = 0.99935, F = 98657.36, s = 3.65);不饱和 链烃，log(741.26-bp) = 2.779526 + 0.0194388~0X~z - 0.0519158~1X~z - 0. 0211047N (R = 0.99467, F = 82387.26, s = 7.74)。应用这些经验公式可以预测 不饱和链烃的沸点。     

脂肪醛和脂肪酮的沸点与分子结构关系的拓扑化学研究

根据分子拓扑学原理,通过采用信息量丰富的染色分子图代替隐氢图,借助于距离矩阵表征分子图中顶点的连接性和标识分子图中顶点性质的差异,发展了一种适用于含杂原子分子体系结构性能研究的新方法,据此探讨了脂肪醛和脂肪酮的沸点与分子结构之间的关系,提出一个既能合理表征结构性能关系、又能预测沸点的定量关系式。结果表明,沸点预测值与实验值的一致性令人满意,平均误差0.21%。     

季铵盐结构与高氯酸根离子选择电极性能关系的研究

本文报道了由七种长链季铵盐制得的高氯酸根离子选择电极,测定了这些电极的Nernst响应范围和检测下限,并研究了各种阴离子的干扰。通过大量实验测得,随着季铵盐分子中取代烷基碳链的增长,电极电势响应范围增宽、检测下限降低、抗外部阴离子干扰能力增强。若取代烷基碳链过长,则季铵盐纯化困难,在膜相中溶解度降低,不适于电极的研制。根据用上述七种选择电极在相同水相条件下测得的数据表明,阴离子的干扰次序为:PA~->ClO_4~->BF_4~->SCN~->I~->ClO_3~->N_3~->N_3~->CN~-～Br~->H_2PO_4~->F~->Cl~-。这些数据对阴离子选择电极研制与相转移催化反应研究均有现实意义。     

n-C3H7I和i-C3H7I的激光裂解

Studies on the photofragmentation of n-C_3H_7I and i-C_3H_7I have been carried out by a photofragment spectrometer with rotatable pulsed molecular beam crossed with KrF excimer laser beam. TOF spectra of the iodine atom fragments (Fig.1, 2) which show the separation of the primary photodissociation channels n-C_3H_7I→n-C_3H_7+I~*(~2P_(1/2)) n-C_3H_7+I(~2p_(3/2)) i-C_3H_7I→i-C_3H_7+I~*(~2P_(1/2)) i-C_3H_7+I(~2P_(3/2)) are obtatned at 12 different angles. The distribution of total translational energy E_(CM) of recoiling photofragments are then determined. The ratios I~*/I of the photodissociation channels of n-C_3H_7I and i-C_3H_7I are measured to be 1.61 and 0.96 respectively (Table 1). The ratios I~*/I obtained by photofragment translational energy measurement in this Lab~[3]. are good in agreement with most of results abtained by IR emission~[5] and LIF~[4] measurement except the data of i-C_3H_7I, which is much different from I~*/I=0.35 reported by Bershon~[4] using LIF method.The extent of internal alkyl fragment excitation E_(int)~R is also determined (Table 2) by energy balance. The fraction of the available energy (E_(av1)=E_(CM)+E_(int)~R) which goes into internal exciatation of the alkyl fragment increases from 12.5% for I~* channe of CH_3I to 64% for both channels of i-C_3H_7I. The results are consistent with direct impulsive dynamic model of unimolecular decomposition based on “soft” alkyl radicals.The facts that the ratio I~*/I decreases with increasing carbon atoms and that the difference of the internal excitation of alkyl radicals between the I~* (~2P_(1/2)) and I (~2P_(3/2)) channelsincreases with increasing carbon atoms should be related and important for better understanding the origin of the I(~2P_(3/2)) channel caused by the potential energy surface crossing~[3]. The results of the internal excitation of the alkyl radicals in the photodissociation are also valuable for prediction of secondary products during the UV photolysis of those alkyl iodides in the gas cell.     

A 13C-NMR and IR study of isocyanides and some of their complexes

¹³C chemical shifts and ¹J(¹⁴N? ¹³C) coupling constants as well as stretching frequencies of the isocyano group are reported for some representative aliphatic, unsaturated and aromatic isocyanides and for two copper(I) isocyanide complexes. The results are discussed in terms of the inductive and mesomeric substituent effects on the polarisation and charge density of the C? N?C bonds. The marked solvent effect on the chemical shifts of the isocyano carbon hampers comparison of our data with previously reported data. The hydrogen bonding shift of this carbon in water or methanol is much smaller than previous data suggest.     

Oxidation of primary aliphatic and aromatic aldehydes with difluoro(aryl)-λ3-bromane

Oxidation of primary aliphatic aldehydes with p-trifluoromethylphenyl(difluoro)-λ(3)-bromane in dichloromethane at 0 °C afforded acid fluorides selectively in good yields, while that of aromatic aldehydes in chloroform at room temperature produced aryl difluoromethyl ethers. A larger migratory aptitude of aryl groups compared to primary alkyl groups during a 1,2-shift from carbon to an electron-deficient oxygen atom in bromane(III) Criegee-type intermediates will result in these differences in the reaction courses.