C60O结构和电子光谱的理论研究

用ＩＮＤＯ系列方法研究Ｃ６０Ｏ的两种结构：一是桥氧加在２个六元环之间的键上为Ｃ２ｖ构型；另一个是桥氧加在１个五元环和１个六元环之间的键上为Ｃｓ构型。计算表明，从总能量、ＨＯＭＯ－ＬＵＭＯ能级差和光谱性质看，Ｃ６０Ｏ的稳定构型都应是Ｃ２ｖ构型，该Ｃ２ｖ异构体具有环氧结构（桥Ｃ１５－Ｃ３０键长为０．１５１８ｎｍ，键序为０．８７４４），其电子光谱计算结果与实验值较好地符合。     

C60CH2结构和电子光谱的理论研究

用ＩＮＤＯ系列方法研究Ｃ６０ＣＨ２的两种结构，ＣＨ２加在两个六元环之间的键上为Ｃ２０构型，ＣＨ２加在一个五元环和一个六元环之间的键上为Ｃ５构型，计算表明，从总能量和ＬＵＭＯ－ＨＯＭＯ能级差看，Ｃ６０ＣＨ２的稳定结构应是Ｃ２０构型，该Ｃ２０异构体有类环丙结构（Ｃ１５－Ｃ３０桥键键长为０．１５５６ｎｍ，键序等于０．８６６３），其电子光谱计算结果与实验值符合较好。     

C60NH^＋2的构型研究及其电子光谱和NMR谱的理论预测

用ＩＮＤＯ系列方法研究Ｃ６０ＮＨ＾＋２的２种构型，一是ＮＨ＾＋２加在２个六元环之间的键上，为Ｃ２构型，另一个是ＮＨ＾＋２加在五元和六元环之间的键上，为Ｃｓ构型，计算表明，Ｃ６０ＮＨ＾＋２的稳定构型应是Ｃ２，且该Ｃ２Ｖ异构体有质子化的环乙亚胺结构（桥Ｃ１５－Ｃ３０为０．１５２０ｎｍ键序为０．９０９７），同时计算了Ｃ６０ＮＨ＾＋２２种构型的电子吸收光谱，讨论了其ＮＭＲ谱，属于理论预测性质。     

C60O3的结构和电子光谱的理论研究

用INDO系列方法对C₆₀O₃的可能构型进行研究,结果表明:环氧结构邻近的6-6键易发生进一步的加成反应.其中3个氧原子加在同一个六元环的6-6边上,形成环氧结构最稳定的C₃v构型,第3个氧原子加在2个环氧结构相邻的六元环的6-6边上的C₂、C_s构型也相当稳定,C₂、C_s构型的部分¹³C NMR谱与实验吻合.C₆₀O₃可能有较好的反应活性,其电子光谱属于理论预测.     

HC60CH2C6H5的结构及光谱的理论研究

用ＩＮＤＯ系列方法研究了由Ｃ６０＾２－制备的衍生物ＨＣ６０ＣＨ２Ｃ６Ｈ５的结构和ＵＶ光谱。结果表明，六元环上的１，２－异构体具有Ｃｓ对称性，１，４－异构体具有Ｃ１对称性。以优化构型为基础，计算两种加成产物的ＵＶ光谱，表明１，２－异构体的特征吸收与实验值相符；同时，对１，４－异构体的ＵＶ光谱进行了理论预测，对电子跃迁进行了理论指认，并分析了光谱红移的原因。     

中间体C60（CH3）^—和产物C60（CH3）2的结构及产物光谱性…

用ＩＮＤＯ系列方法对Ｃ＾２－６０与ＣＨ３反应的中间体Ｃ６０（ＣＨ３）＾－进行理论研究。得到具有Ｃ，对称性的构型，结果表明，ＣＨ３加成到Ｃ１５上，将使与共相邻的双键碳（Ｃ３０）的电荷密度和自旋密度达极大值，故加成反应部位在Ｃ３０处；另外，Ｃ１５的对位Ｃ１２也较其它部位易于反应，且有两个反应场所，因而产物Ｃ６０（ＣＨ３）２可能为六元环上的１，２－加成和１，４－加成两种异构体的混合物，同时对两种加成产物     

C~6~0SiH~2的结构和电子光谱的量子化学研究

用INDO系列方法研究了C~6~0SiH~2的两种结构: 一是SiH~2加在两个六元环之间的键上形成C~2~v构型; 另一是SiH~2加在一个五元环和一个六元环之间的键上形成C~s构型。从总能量和LUMO-HOMO能级差看, C~6~0SiH~2的稳定结构应是C~2~v构型, 其中桥C(15)-C(30)的键长为0.1508nm, 键序为0.9369, 说明不开环, 形成类环丙烷结构。文中计算了两种构型的电子吸收光谱和NMR谱, 此类计算是基于对C~6~0SiH~2的等电子体C~6~0O和C~6~0CH~2的研究之上, 且后两者的研究结果与实验相一致。     

C60^2—单态的Jahn—Teller畸变和光谱性质

用ＩＮＤＯ系列方法，对Ｃ６０＾２－单态进行几何构型优化，得到３种不同对称性的构型：Ｄ５ｄ，Ｄ３ｄ，Ｄ２４，表明Ｃ６０＾２－已发生Ｊａｈｎ－Ｔｅｌｌｅｒ畸变，Ｄ５ｄ有４种原子７种键；Ｄ３ｄ有６种原子１０种键；Ｄ２ｈ有９种子１５种键，额外负电荷主要分布在赤道附近，以这３种构型为基础分别计算了Ｃ６０＾２－单态的电子光谱，说明Ｃ６０＾２－的基态应该是三态。     

Jahn—Teller变形后—C60^—的结构和电子学谱

用ＩＮＪＤＯ系列方法对Ｃ６０＾－进行几何构型优化，得到Ｄ３ｄ对称性的构型，表明Ｃ６０＾－确实发生了Ｊａｈｎ－Ｔｅｌｌｅｒ畸变，导致单键变短，双键变长，形成１０种键，６种不等同碳原子，并以此构型为基础，计算了Ｃ６０＾－的电子光谱，与实验结果吻合；同时对光谱进行了理论指认；最后对Ｃ＾６０－的３种构型：Ｄ５ｄ，Ｄ３ｄ，Ｄ２ｈ的几何构型、能量、光谱和反应特性进行了分析、比较和总结。     

C59O的结构,电子光谱及NMR谱的理论预测

用ＩＮＤＯ系列方法对Ｃ６０的取代产物Ｃ５９Ｏ进行几何构型优化，得到Ｃｓ对称性的稳定构型，以此构型为基础，计算并预测了Ｃ５９Ｏ的电子光谱和ＮＭＲ谱。最后与Ｃ５９Ｏ的等电子分子体Ｃ＾２－６０及Ｃ６０Ｏ进行了比较。     

Molecular structures of benzoic acid and 2-hydroxybenzoic acid, obtained by gas-phase electron diffraction and theoretical calculations

The structures of benzoic acid (C6H5COOH) and 2-hydroxybenzoic acid (C6H4OHCOOH) have been determined in the gas phase by electron diffraction using results from quantum chemical calculations to inform restraints used on the structural parameters. Theoretical methods (HF and MP2/6-311+G(d,p)) predict two conformers for benzoic acid, one which is 25.0 kJ mol(-1) (MP2) lower in energy than the other. In the low-energy form, the carboxyl group is coplanar with the phenyl ring and the O-H group eclipses the C=O bond. Theoretical calculations (HF and MP2/6-311+G(d,p)) carried out for 2-hydroxybenzoic acid gave evidence for seven stable conformers but one low-energy form (11.7 kJ mol(-1) lower in energy (MP2)) which again has the carboxyl group coplanar with the phenyl ring, the O-H of the carboxyl group eclipsing the C=O bond and the C=O of the carboxyl group oriented toward the O-H group of the phenyl ring. The effects of internal hydrogen bonding in 2-hydroxybenzoic acid can be clearly observed by comparison of pertinent structural parameters between the two compounds. These differences for 2-hydroxybenzoic acid include a shorter exocyclic C-C bond, a lengthening of the ring C-C bond between the substituents, and a shortening of the carboxylic single C-O bond.     

Stabilities and Electronic Spectra for C78O2 Isomers

1 INTRODUCTION Functional derivatives of fullerenes have aroused chemists’ interest and monofunctional products are accompanied by difunctional derivatives[1～3]. Diede- rich[1] prepared and detected C70O2 by the FAB mass spectrum. Kalsbeck[2] synthesized C60On (n = 1～4) by electrochemical oxidation of C60. Wood[3] investi- gated photolysis of a crude fullerene mixture and obtained C60On (n = 2～5) and C70O2. Menon[4] stu- died the optimized structures and electronic proper- ties o…     

自由基C69N及双体(C69N)2结构和电子光谱的理论研究

用INDO系列方法对自由基C₆₉N(Cs)及双体(C₆₉N)₂(C₂h)进行了理论研究,结果表明:笼骨架上N的掺入使C₇₀笼发生畸变,N向笼外突出,与氮相连的碳(6-6环上的C)自旋密度较大,2个C₆₉N自由基在这个碳上以C-C单键连接,形成双体为C₂h对称性,N与附近的3个碳均以单键连接,并不断开。理论计算的电子光谱与实验吻合较好,(C₆₉N)₂易分解为单体C₆₉N.     

C78O异构体的电子结构和光谱

The semi-empirical INDO method was used to study the electronic structures and the spectra of all of the 34 possible isomers of C78O based on C78 with group C2v. This calculation can simulate positions of an additional oxygen atom in C78 and predict the spectroscopic characteristics of the isomers. The most stable geometry of C78O is the 73,78-C78O molecule with an epoxide structure. The added 73,78-bond is located between two hexagons (6-6) and is intersected by the shortest C2 axis in C78 with group C2v. Atomic orbitals of the oxygen atom play an important role in lowering HOMO energy of 73,78-C78O. Compared with C78 with group C2v, the blue-shift in the electronic absorption spectrum for 73,78-C78O was observed.The reason of the blue-shift effect was discussed, and the electronic transitions were assigned based on the theoretical calculations.     

Hydrogen bonding incis-2,3-epoxycyclooctanol

Hydrogen bonding and the electron-withdrawing or electron-donating characteristics of substituent groups that are neighboring to epoxide groups can affect the reactivity of the epoxide ring. The crystal structure ofcis-2,3-epoxycyclooctanol has been determined as a saturated eight-membered ring compound in which a hydroxyl group is attached to the C(1) atom that is adjacent to a 2,3-fused epoxy ring. The findings are that the longer epoxide C-O bond (and hence the one expected to be more readily broken) is the one farther from the hydroxyl group [1.462(1) å versus 1.447(1) å] and that the optimal hydrogen bonding is to an adjacent molecule radier than within the molecule. The shortest C-C bond is that of the epoxide group; the bond adjacent to it (on the side farther from the hydroxyl group) is the next shortest.     

First principles study on the solvation and structure of C2O4(2-)(H2O)n, n = 6-12

The structures and energies of hydrated oxalate clusters, C2O4(2-)(H2O)n, n = 6-12, are obtained by density functional theory (DFT) calculations and compared to SO4(2-)(H2O)n. Although the evolution of the cluster structure with size is similar to that of SO4(2-)(H2O)n, there are a number of important and distinctive futures in C2O4(2-)(H2O)n, including the separation of the two charges due to the C-C bond in C2O4(2-), the lower symmetry around C2O4(2-), and the torsion along the C-C bond, that affect both the structure and the solvation energy. The solvation dynamics for the isomers of C2O4(2-)(H2O)12 are also examined by DFT based ab initio molecular dynamics.     

Selective preparation of oxygen-rich [60]fullerene derivatives by stepwise addition of tert-butylperoxy radical and further functionalization of the fullerene mixed peroxides

tert-Butylperoxy radicals add to C(60) selectively to form multi-adducts C(60)(O)(m)(OO(t)Bu)(n) (m = 0, n = 2, 4, 6; m = 1, n = 0, 2, 4, 6) in moderate yields under various conditions. Visible light irradiation favors epoxide formation. High concentration of tert-butylperoxy radicals mainly produces the hexa-homoadduct C(60)(OO(t)Bu)(6) 6; low concentration and long reaction time favor the epoxy-containing C(60)(O)(OO(t)Bu)(4) 7. The reaction can be stopped at the bis-adducts with limited TBHP. A stepwise addition mechanism is discussed involving mono-, allyl-, and cyclopentadienyl C(60) radical intermediates. m-CPBA reacts with the 1,4-bis-adduct to form C(60)(O)(OO(t)Bu)(2) and C(60)(O)(3)(OO(t)Bu)(2). The C-O bond of the epoxy ring in 7 can be cleaved with HNO(3) and CF(3)COOH. Nucleophilic addition of NaOMe to 7 follows the S(N)1 and extended S(N)2' mechanism, from which four products are isolated with the general formula C(60)(O)(a)(OH)(b)(OMe)(c)(OO(t)Bu)(d). Visible light irradiation of the hexa-adduct 6 results in partial cleavage of both the C-O and O-O bonds of peroxide moieties and formation of the cage-opened compound C(60)(O)(O)(2)(OO(t)Bu)(4). All the fullerene derivatives are characterized by spectroscopic data. A single-crystal structure has been obtained for an isomer of C(60)(O)(OH)(2)(OMe)(4)(OO(t)Bu)(2).     

烯丙基自由基(·C3H5)与氧气(O2)反应机理的理论计算

用量子化学计算方法对CH3CH=·CH与O2气的反应机理进行了理论研究, 在B3LYP/6-311G(d,p) 水平下优化稳定分子结构和寻找过渡态, 并在此构型的基础上, 采用CCSD(T)/6-311G(d,p)方法得到各驻点的高级单点能量. 找到主要路径R(CH3CH=·CH+O2)→m1(trans-CH3CH=CHOO)→m2(形成COO三元环)→m3(C—C键断裂,同时生成CH3CH—O—CHO)→P2(C—O键断裂生成CH3CHO+CHO); 并与C2H3等共轭体系进行了对比.     

Gas electron diffraction analysis on S-methyl thioacetate, CH3C(O)SCH3

The molecular structure of S-methyl thioacetate, CH3C(O)SCH3, was determined by gas electron diffraction (GED) with the assistance of quantum chemical calculations (B3LYP/6-31G and MP2/6-31G). Experimental and theoretical methods result in a structure with syn conformation (C=O double bond syn with respect to the S-C(H3) single bond). The following skeletal geometric parameters were derived from the GED analysis (ra values with 3sigma uncertainties): C=O = 1.214(3), C-C = 1.499(5), S-C(sp2) = 1.781(6), S-C(sp3) = 1.805(6) angstroms, O=C-C = 123.4(8) degrees, O=C-S = 122.8(5) degrees and C-S-C = 99.2(9) degrees.