ClF_3O和环氧丙烷反应的理论研究（英文）

应用密度泛函理论对ClF3O和环氧丙烷的反应机理进行了研究。在B3PW91/6-31++G(d,p)水平上优化了各驻点(反应物、中间体、过渡态和产物)的几何构型,并计算了它们的振动频率和零点振动能。采用CCSD(T)/6-31++G(d,p)//B3PW91/6-3l++G(d,p)单点能计算方法求得各物质的能量,并做零点能校正。计算结果表明,ClF3O与C3H6O可经过不同的反应路径,引发C3H5O自由基和ClOF2自由基生成环氧丙醇和三氟化氯,其中,位于ClF3O周向位置的F原子与C3H6O的C(7)上与CH3异侧的H(9)原子结合的活化能最低,仅15.63kJ/mo1;ClF3O与C3H6O反应生成的C3H5O自由基和ClOF2自由基继续反应,经过不同反应路径生成C3H4O、ClOF和HF,其中,ClOF2中的F原子和C3H5O中的H(2)或H(4)原子结合是无能垒的过程。整个反应的主要路径为C3H6O+ClF3O→TS12→P4(C3H5O+HF+ClOF2)→P12(CH2CHCHO+2HF+ClOF)。     

自由基-分子反应:F+Propene(CH2CHCH3)的从头算研究

采用从头算CCSD(T)/6-311 G(2d,2p)//B3LYP/6-311G(d,p)方法,研究了自由基-分子反应F CH2CHCH3的各种不同的反应通道．该反应主要是通过复合物形成机制进行,即F分别加到碳碳双键的两端形成自由基复合物1和2．这两种亚稳态自由基会解离成三种产物:H C3H5F、CH3 C2H3F和HF C3H5．理论计算结果表明,生成CH3 C2H3F是反应的主要通道,而生成H C3H5F和HF C3H5对产物也有一定的贡献．这一结果和实验符合得很好．     

AIM Study on the Reaction of CH2SH Radical with Fluorine Atom

采用MP2(Full)/6-311G(d,p)、QCISD(T)/6-311++G(2df,p)和B3LYP/6-311G(d,p)方法研究了CH2SH自由基与F原子的反应．F原子通过进攻自由基上的C原子或S原子形成三种不同的反应通道．计算结果表明F原子进攻自由基上的C原子生成CH2S和HF为主要的反应通道．对反应进程中若干关键点进行了电子密度拓扑分析,找到了该反应的结构过渡区(结构过渡态)和能量过渡态．计算结果表明,对于比较显著的吸热或放热反应,其结构过渡区范围很小,对于吸热或放热不太显著的反应,结构过渡区范围较大.     

CH3CH2+O(3P)反应机理的理论研究

利用abinitio方法对CH3CH2+O(3P)反应进行了理论研究,在MP2/6311+G(d,p)水平上优化得到了反应途径上的反应物、中间体、过渡态和产物的几何构型和谐振频率,并在QCISD(T)/6311+G(d,p)水平上进行单点能计算.计算结果表明:CH2O+CH3、CH3CHO+H和CH2CH2+OH是主要反应产物,其中CH2O+CH3主要来自反应通道A1:(R)→IM1→TS3→(A),CH3CHO+H主要来自反应通道B1:(R)→IM1→TS4→(B),CH2CH2+OH主要来自直接抽提反应通道C1和C2:(R)→TS1(TS2)→(C).计算结果同时表明该反应生成CO的通道能垒是非常高的,CO应该不是主要产物.     

CH2Cl与OH自由基反应机理的理论研究

用量子化学从头算方法对CH2 Cl与OH自由基反应生成HCCl+H2 O、HCOCl+H2 和H2 CO +HCl的机理进行了研究 .在UMP2 (FC) / 6 311++G 水平上计算出了各物种的优化构型、振动频率 ;并在Gaussian 3(G3)水平上计算了他们的零点能 (ZPE)、相对能量及总能量 .结果表明 ,CH2 Cl和OH自由基反应首先经无垒过程生成一个富能中间体CH2 ClOH ,中间体再经过一系列原子转移、基团旋转和键断裂分别生成产物HCCl+H2 O、HCOCl+H2 和H2 CO +HCl;三者均为放热反应 ,放热量分别为 72 .81、338.5 4和 35 4 .0 8kJ/mol;生成H2 CO +HCl放出的热量比生成HCCl+H2 O放出的热量多 2 81.2 7kJ/mol,与实验结果吻合 .     

VO2+与CH3CHO反应机理的密度泛函研究

用密度泛函方法在B3LYP/6-311G(d, p)水平上研究了VO2+氧化CH3CHO的反应机理。计算结果表明VO2+氧化CH3CHO的优势反应路径为：首先,CH3CHO与1VO2+ 或 3VO2+通过无能垒的放热反应形成配合物;然后,VO2+的O原子进攻CH3CHO分子中-CHO的C原子,形成四元环中间体;最后,通过H迁移反应形成1VO+ 或 3VO+ 与CH3COOH的配合物。     

CH3CH2O及CH3CHOH与HO2反应机理的理论研究

采用CCSD(T)/cc-pVTZ//B3LYP/6-311++G(2df,2p)水平上对CH3CHOH + HO2和CH3CH2O + HO2反应体系的单、三重态反应机理进行了详细的理论研究.计算结果表明,CH3CHOH + HO2反应主要发生在单重态势能面上,其中四条通道均为快速自发过程;CH3CH2O + HO2反应在三重态势能面上的通道CH3CH2O + HO2 → 3IM11 → 3TS11 → P11 (CH3CH2OH + 3O2)为动力学和热力学的优势路径. 大气中CH3CHOH比CH3CH2O更容易稳定存在.     

OH+C_2H_3F的反应机理及产物支化比反应的理论研究（英文）

木文对HOC_2H_3F可能解离通道的势能面进行从头算CCSD(T)/CBS//B3LYP/6-311G(d,p)计算,同时对速率常数进行Rice-Ra msperger-Kassel-Marcus计算.生成主要产物CH2CHO+HF最有利的反应途径是OHC_2H_3F→i2→TS14→i6→TS9→i3→TS3→CH_2C HO+HF,其中速率决定步骤是HF通过TS11从CO桥接位置解离,能量比反应物高3.8 kcal/mol.借助中间态TS14,F原子从C_β迁移到C_α位置生成CH_2O+CH_2F,然后通过中间态TS16,H从O迁移到C_α位置;通过中间态TS5,C-C键断裂生成产物,其能量比反应物低1.8 kcal/mol,比TS11低4.0 kcal/mol.     

CH3与NO2的反应

用时间分辨傅立叶红外光谱法和量子化学计算，研究了CH3自由基与NO2的基元反应．由248 nm激光光解CH3Br或CH3I得到CH3自由基．首次观测到了振动激发的产物OH、HNO和CO2．另一产物NO也被证实．由此确定了反应通道CH3O+NO，CH2NO+OH 和HNO+H2CO．其中CH3O+NO是主要的反应通道．还用CCSD(T)/6-311++G(df,p)//MP2/6-311G(d,p)的方法对上述通道的机理在理论上做了研究．理论计算的结果与实验观察相符．     

CH3CH2O及CH3CHOH与HO2反应机理的理论研究

采用CCSD(T)/cc-pVTZ//B3LYP/6-311++G(2df,2p)水平上对CH3CHOH + HO2和CH3CH2O + HO2反应体系的单、三重态反应机理进行了详细的理论研究.计算结果表明,CH3CHOH + HO2反应主要发生在单重态势能面上,其中四条通道均为快速自发过程;CH3CH2O + HO2反应在三重态势能面上的通道CH3CH2O + HO2 → 3IM11 → 3TS11 → P11 (CH3CH2OH + 3O2)为动力学和热力学的优势路径. 大气中CH3CHOH比CH3CH2O更容易稳定存在.     

The Atomic Structure of Oxide/Oxide Interface

The physical and chemical properties of thin or ultrathin oxide film deposited on another oxide bulk or thin film usually differ strongly from the bulk. The properties of the heterostructures ultimately rely on the structure and the chemistry of the oxide/oxide interface. Data in the literature indicated that atomically abrupt interfaces between oxides show abnormal electronic and magnetic properties. This article reviews the interfacial structures of oxide/oxide interfaces in an atomic scale. The origins of the unique physical and chemical properties at the oxide/oxide interfaces are also discussed.     

抗水化氧化钙坩埚制备技术

采用二次烧结方法，并控制颗粒级配，制备了不同氧化铁添加剂含量的氧化钙试样，测量了试样的抗水化性能。结果表明，加入氧化铁能提高氧化钙材料的抗水化性能，加入3Wt％氧化铁能制备出具有较好的抗水化性能的氧化钙坩埚。     

Functionalization of Graphene Oxide and its Biomedical Applications

Graphene oxide (GO) offers interesting physicochemical and biological properties for biomedicine due to its versatility, biocompatibility, small size, large surface area, and its ability to interact with biological cells and tissues. GO is a two-dimensional material of exceptional strength, unique optical, physical, mechanical, and electronic properties. Ease of functionalization and high antibacterial activity are two major properties identified with GO. Due to its excellent aqueous processability, amphiphilicity, surface functionalization capability, surface enhanced Raman scattering (SERS), and fluorescence quenching ability, GO chemically exfoliated from oxidized graphite is considered a promising material for biological applications. In addition, due to π-π* transitions, a low energy is required for electron movement, a property important in Biosensor and Bioimaging applications of GO. In this article, we present an overview of current advances in GO applications in biomedicine and discuss future perspectives. We conclude that GO is going to play a vital role in Biomedical applications in the near future.     

钒氧化物薄膜的拉曼散射

用射频磁控溅射以纯金属钒做靶材在氩氧混合气体中制备了钒氧化物 (VO2 (B)、V6O1 3、V2 O5)薄膜。报导了钒氧化物薄膜的拉曼光谱 ,结合这些钒氧化物不同的结构特点 ,对它们的拉曼光谱进行了分类讨论     

Porous Lanthanum-Doped Manganese Oxide Nanoparticles for Enhanced Sonodynamic Cancer Therapy

Metal oxides hold great promise as robust sonosensitizers for sonodynamic therapy (SDT). However, they usually suffer from limited production yield of reactive oxygen species (ROS) due to the fast recombination of ultrasound-triggered electrons and holes. Herein, porous lanthanum (La)-doped MnO₂ (LMO) nanoparticles are firstly developed as promising sonosensitizers in SDT. The strategic introduction of La dopants greatly promotes the separation efficiency of ultrasound-triggered electrons and holes of MnO₂, endowing them with significantly improved ROS yield. Consequently, the LMO with polyethylene glycol decoration exhibits good SDT activity toward breast cancer cells. This work highlights the doping strategy for the development of enhanced ROS production of metal oxide sonosensitizers for SDT.     

Oxygenated Functional Group Density on Graphene Oxide: Its Effect on Cell Toxicity

The association of cellular toxicity with the physiochemical properties of graphene‐based materials is largely unexplored. A fundamental understanding of this relationship is essential to engineer graphene‐based nanomaterials for biomedical applications. Here, an in vitro toxicological assessment of graphene oxide (GO) and reduced graphene oxide (RGO) and in correlation with their physiochemical properties is reported. GO is found to be more toxic than RGO of same size. GO and RGO induce significant increases in both intercellular reactive oxygen species (ROS) levels and messenger RNA (mRNA) levels of heme oxygenase 1 (HO1) and thioredoxin reductase (TrxR). Moreover, a significant amount of DNA damage is observed in GO treated cells, but not in RGO treated cells. Such observations support the hypothesis that oxidative stress mediates the cellular toxicity of GO. Interestingly, oxidative stress induced cytotoxicity reduces with a decreasing extent of oxygen functional group density on the RGO surface. It is concluded that although size of the GO sheet plays a role, the functional group density on the GO sheet is one of the key components in mediating cellular cytotoxicity. By controlling the GO reduction and maintaining the solubility, it is possible to minimize the toxicity of GO and unravel its wide range of biomedical applications.     

Lanthanum Oxide Effects on the Structure of Calcium Phosphate Glasses

Calcium phosphate glasses, in which part of calcium oxide was replaced by lanthanum oxide, were prepared by using the conventional melt quench method. The structures of xLa₂O₃ · (50-x)CaO · 50P₂O₅ (x = 0, 1, 3, 6, 12 mol%) samples were investigated by X-ray diffraction (XRD), Raman spectrum, Fourier transform infrared spectrum (FTIR), and differential scanning calorimetry (DSC). The results show that lanthanum oxide acts as network modifier in the network space of glass structure. The glass formation occurs at an O/P ratio of about 3.0–3.12. At larger values, the crystalline phases calcium pyrophosphate (Ca₂P₂O₇) and calcium lanthanum phosphate [Ca₉La(PO₄)₇] are detected in the samples. Raman and FTIR spectra indicate that the structure of lanthanum-free sample is chain P–O–P bond metaphosphate–based Q² units. Glass structure will change to Q² and Q¹ units when the lanthanum oxide content is less then 6 mol%. When lanthanum oxide content increases to 9 and 12 mol% more nonbridging oxygen in the glass, resulting in the depolymerization of the phosphate network, the network of glass transforms to Q², Q¹, and Q⁰ units mixture. Based upon DSC results, T_g slightly decreases because of the depolymerization of microstructure. Endothermal peak of DSC curves indicate that crystal phases separate out from vitreous body with the addition of lanthanum oxide content.     

化学溶液沉积制备氧化石墨烯掺杂YBCO薄膜

YBCO薄膜在液氮温区具有优异的性能,围绕低成本溶液沉积技术和新型添加剂的研究是目前研究热点.采用化学溶液沉积技术成功制备出氧化石墨烯掺杂YBCO薄膜。通过在YBCO前驱液中引人氧化石墨烯,改变YBCO胶体的热解行为,促进YBCO前驱体的分解.在晶化过程中,氧化石墨烯有利于抑制YBCO晶粒长大.结果表明,适量添加氧化石墨烯可以改善YBCO薄膜的微观形貌和外延生长,提高超导层的性能.