肾上腺素与胞嘧啶相互作用的密度泛函理论研究

采用密度泛函理论（DFT）B3LYP方法和6-311＋G（d,p）基组对肾上腺素-胞嘧啶复合物进行结构优化和频率计算,得到15种稳定的复合物.研究发现,所有的复合物进行基组重叠误差（BSSE）校正后的相互作用能为-11.43^-48.96kJ/mol,符合氢键能量范围,相互作用能主要由氢键所贡献.结构和振动频率分析显示,氢键的形成使相应O（N）—H键的键长变长,对称伸缩振动频率减小,说明复合物中形成的氢键都是正常的红移型氢键.应用自然键轨道（NBO）理论和分子中的原子（AIM）理论对15种复合物的氢键性质和特征进行分析,发现氢键对于复合物的稳定性起着重要作用,当复合物形成2个或更多的氢键时,氢键的数目、类型及强度共同决定着复合物的稳定性,复合物基本符合三氢键〉二氢键〉单氢键的稳定顺序,三氢键复合物4是最稳定的,复合物3存在单氢键O—H…O,比部分二氢键复合物要稳定.     

木犀草素与胞嘧啶相互作用的理论研究

采用密度泛函理论中的B3LYP方法,在6-31＋G＊基组水平上对木犀草素、胞嘧啶、木犀草素-胞嘧啶复合物进行结构优化和振动频率分析,得到了12种稳定复合物.并应用分子中的原子理论（AIM）分析、自然键轨道（NBO）理论分析得到复合物氢键性质和特征.通过基组重叠误差（BSSE）校正后的相互作用能、成键临界点电荷密度、二阶...     

胞嘧啶…NO复合物结构与性质的理论研究

用密度泛函理论在BL3YP/6-311＋G*基组水平上对胞嘧啶…NO复合物体系进行了理论计算, 发现了6个能量极小的复合物. 其结合方式是NO的N或O原子与胞嘧啶的N—H键形成氢键, 最稳定的复合物的结合能为－9.65 kJ/mol. NO的N原子与胞嘧啶的结合具有更强的优势, N结合的复合物中NO的键长缩短, 而O结合的复合物中NO键长伸长. 同时, 对复合物的振动分析发现, 在胞嘧啶中所有的与NO结合的N—H键的伸缩频率下降, 而所有氨基的面内弯曲振动频率是增加的.     

4-羟甲基吡啶－水红移氢键的密度泛函理论研究

使用密度泛函理论B3LYP方法和6-311++G**基函数对4-羟甲基吡啶与水形成的1:1和1:2（摩尔比）氢键复合物进行了理论计算研究,分别得到稳定的4-羟甲基吡啶－H₂O和4-羟甲基吡啶－(H₂O)₂氢键复合物3个和8个。经基组重叠误差和零点振动能校正后,最稳定的1:1和1:2氢键复合物的相互作用能分别为-20.536和-44.246 kJ/mol。振动分析显示O-H···N(O)氢键的形成使复合物中O-H键对称伸缩振动频率红移(减小)。自然键轨道分析表明,4-羟甲基吡啶与水形成最稳定的1:1和1:2氢键复合物时,分子间电荷转移分别为0.02642 e 和0.03813 e 。含时密度泛函理论TD-B3LYP/ 6-311++G**计算显示,相对于4-羟甲基吡啶单体分子,氢键H-OH···N和H-OH···OH的形成分别使最大吸收光谱波长兰移8~16纳米和红移4~11纳米。     

CH_3SH和CH_3SLi分子间的锂键和氢键共存型相互作用

在CH3SLi+CH3SH势能面上求得锂键和氢键共存型复合物的两种稳定构型.频率分析表明,与单体相比复合物中S(5)—Li(6)键伸缩振动频率发生红移,而C(8)—H(10)键伸缩振动频率发生蓝移.经B3LYP/6-311++G**,MP2/6-311++G**及MP2/AUG-CC-PVDZ水平计算的含基组重叠误差(BSSE)校正的复合物Ⅰ中相互作用能分别为-58.99,-57.87和-62.89kJ·mol-1.采用自然键轨道(NBO)理论,分析了复合物中单体轨道间的电荷转移,电子密度重排及其与相关键键长变化的本质等.采用分子中的原子(AIM)理论分析了复合物中氢键和锂键的电子密度拓扑性质.在极化连续模型(PCM)下,考察了溶剂化效应.结果表明,所考察的水、二甲亚砜、乙醇和乙醚等四种溶剂均使单体间的相互作用能增大,且溶剂对复合物中的锂键结构及其振动频率具有显著的影响,而对复合物中的氢键的振动频率影响不大.     

复合物C2H6·(H2O)2中分子间相互作用的理论研究

在B3LYP/6-311 G**水平上得到C2H6.(H2O)2复合物势能面上四种稳定构型。在相同基组下经MP2电子相关能和基组叠加误差(BSSE)进行单点能量校正,求得单体间相互作用能的大小。结果发现:四种稳定构型都通过CH…O氢键而形成,相应σ(CH)键都出现了较小的收缩,导致伸缩振动发生蓝移,在最稳定的复合物Comp lex2和Comp lex3中,H2O(A)分子的一个H原子与C2H6的两个H原子相对距离较短,并且具有最大的总相互作用能和两个单体AC分子间相互作用能,这说明三个氢原子间存在着较强的相互作用,并对分子的稳定性起着重要作用.     

吡咯-HCN体系在气相及溶液中相互作用的理论研究

用量子化学B3LYP方法在6-311G(d, p)水平上优化了吡咯-HCN氢键复合物，通过振动频率分析确定了两个吡咯-HCN体系稳定构型.为了得到更加精确的氢键作用能，采用相关一致基组aug-cc-pVDZ以及Boys 和Bernardi的CP(counterpoise)校正方法消除基组重叠误差后得到C－H…π和N－H…N型复合物的氢键相互作用能.为了确定B3LYP方法计算的相互作用能的可靠性，在MP2/aug-cc-pVDZ水平计算了复合物的氢键相互作用能，结果分别为－25.10和－19.30 kJ·mol－1.采用自然键轨道(NBO)分析考察了吡咯与HCN分子间轨道相互作用.以自洽场理论(SCRF)中的Onsager模型研究了不同极性溶剂对吡咯-氰化氢体系N－H…N型氢键几何构型，频率位移，电荷分布以及相对能量的影响.研究发现，当溶液的介电常数在1.5～30.0范围时，溶液作用十分显著，而当介电常数超过30.0以后，溶液作用已经达到了极限.     

氮杂杯[2]-间/对-芳烃[2]三嗪与RDX氢键作用理论研究

利用MP2和mPWPW91方法,在6-311G**和6-311++G**基组水平上研究了RDX分别与硝基、氨基和迭氮基取代的氮杂杯[2]-间-芳烃[2]三嗪和氮杂杯[2]-对-芳烃[2]三嗪形成的分子间氢键相互作用,并借助自然键轨道(NBO)和分子中的原子(AIM)理论揭示了氢键的本质.结果表明,氮杂杯[2]-间-芳烃[2]三嗪复合物中氢键主要发生在RDX与三嗪环及其取代基之间;氮杂杯[2]-对-芳烃[2]三嗪复合物中氢键主要发生在RDX与杯芳烃环及其取代基之间.分子间相互作用能在-18.82~-40.62kJ/mol之间;经基组叠加误差(BSSE)校正后,相互作用能顺序为e>f≈b>a>c>d和e′>b′>f′>a′>d′>c′.两类复合物中,氨基取代的复合物分子间氢键强于硝基或叠氮基复合物分子间氢键,氨基氮杂杯[2]-对-芳烃[2]三嗪与RDX形成的氢键最强,有望作为降低火炸药感度、进行火炸药废水处理的候选物.为获得稳定性较强的RDX-氨基氮杂杯芳烃超分子炸药,应该选取介电常数较大的溶剂.     

s-四嗪-水簇复合物的理论研究

用量子化学B3LYP方法和6-31＋＋G**基函数研究了s-四嗪-水簇复合物基态分子间相互作用, 并进行了构型优化和频率计算, 分别得到无虚频稳定的s-四嗪-(水)₂复合物、s-四嗪-(水)₃复合物和s-四嗪-(水)₄复合物6个、9个和12个. 复合物存在较强的氢键作用, 复合物结构中形成一个N…H—O氢键并终止于O…H—C氢键的氢键水链构型最稳定. 经基组重叠误差和零点振动能校正后, 最稳定的1∶2, 1∶3和1∶4(摩尔比)复合物的结合能分别是41.35, 70.9和 94.61 kJ/mol. 振动分析显示氢键的形成使复合物中水分子H—O键对称伸缩振动频率减小(红移). 研究表明N…H键越短, N…H—O键角越接近直线, 稳定化能越大, 氢键作用越强. 同时, 用含时密度泛函理论方法在TD-B3LYP/6-31＋＋G**水平计算了s-四嗪单体及其氢键复合物的第一¹(n, p*)激发态的垂直激发能.     

带电组氨酸侧链与DNA碱基间非键作用强度的理论研究

采用MP2方法和6-31+G(d,p)基组优化得到了带有一个正电荷的组氨酸侧链与4个DNA碱基间形成的18个氢键复合物的气相稳定结构, 从文献中获取了组氨酸侧链与DNA碱基间形成的12个堆积和T型复合物的气相稳定结构, 使用包含基组重叠误差(BSSE)校正的MP2方法和aug-cc-pVTZ基组及密度泛函理论M06-2X-D3方法和aug-cc-pVDZ基组计算了这些复合物的结合能. 研究结果表明, 包含BSSE校正的M06-2X-D3方法和aug-cc-pVDZ基组能够给出较准确的结合能; 气相条件下, 组氨酸侧链与同种DNA碱基间的离子氢键作用明显强于堆积作用和T型作用, 组氨酸侧链最易通过离子氢键与胞嘧啶C和鸟嘌呤G作用形成氢键复合物, 组氨酸与胞嘧啶C和鸟嘌呤G间的T型作用强于与腺嘌呤A和胸腺嘧啶T间的离子氢键作用; 水相条件下, 组氨酸侧链与同种DNA碱基间的离子氢键作用仍明显强于堆积作用和T型作用, 组氨酸侧链更易与胞嘧啶C和鸟嘌呤G相互作用形成氢键复合物, 但是最强的组氨酸侧链与胞嘧啶C间的T型作用明显弱于与腺嘌呤A和胸腺嘧啶T间的离子氢键作用, 说明水相条件下组氨酸侧链与DNA碱基间主要通过离子氢键作用形成氢键复合物.     

Density Functional Theory Study of the Interaction between Guanine and Catechin

The interacting patterns and mechanism of the catechin and guanine have been investigated with the density functional theory B3LYP method by 6‐31G* basis set. Fourteen stable structures for the catechin‐guanine complexes have been found which form two hydrogen bonds at least. The results indicate that the complexes are mainly stabilized by the hydrogen bonding interactions. At the same time, the number and strength of hydrogen bond play a co‐determinant parts in the stability of the complexes which can form two or more hydrogen bonds. Theories of atoms in molecules (AIM) and natural bond orbital (NBO) have been adopted to investigate the hydrogen bonds involved in all systems. The interaction energies of all complexes have been corrected for basis set superposition error (BSSE), ranging from ?38.86 to ?14.56 kJ/mol. The results showed that the hydrogen bonding contributes to the interaction energies dominantly. The corresponding bonds stretching motions in all complexes are red‐shifted relative to that of the monomer, which is in agreement with experimental results.     

Density Functional Theory Study of the Interaction between Thymine and Luteolin

The density function B3LYP method has been used to optimize the geometries of the luteolin, thymine and luteolin‐thymine complexes at 6‐31+G?? basis. The vibrational frequencies have been studied at the same level to analyze these seventeen complexes, respectively. Theories of atoms in molecules (AIM) and natural bond orbital (NBO) have been utilized to investigate the hydrogen bonds involved in all the systems. The interaction energies of the complexes corrected by basis set superposition error are between ?93.00–?76.69 kJ/mol. The calculating results indicate that strong hydrogen bonding interactions have been found in the luteolin‐thymine complexes.     

Density Functional Theory Study on Interaction between Catechin and Thymine

The interacting patterns and mechanism of the catechin and thymine have been investigated with the density functional theory Becke's three-parameter nonlocal exchange functional and the Lee, Yang, and Parr nonlocal correlation functional (B3LYP) method by 6-31+G*basis set. Thirteen stable structures for the catechin-thymine complexes have been found which form two hydrogen bonds at least. The vibrational frequencies are also studied at the same level to analyze these complexes. The results indicated that catechin interactedwith thymine by three different hydrogen bonds as N-H…O、C-H…O、O-H…O and the complexes are mainly stabilized by the hydrogen bonding interactions. Theories of atoms in molecules and natural bond orbital have been adopted to investigate the hydrogen bondsinvolved in all systems. The interaction energies of all complexes have been corrected for basis set superposition error, which are from -18.15 kJ/mol to -32.99 kJ/mol. The results showed that the hydrogen bonding contribute to the interaction energies dominantly. The corresponding bonds stretching motions in all complexes are red-shifted relative to that of the monomer, which is in agreement with experimental results.     

Quantum Study on the Hydrogen Bonding Interaction of Luteolin-（CH_3OH）_n

The optimized geometries and vibration frequencies of luteolin,methanol and luteolin-(CH3OH)n complexes have been investigated by density functional theory using B3LYP method.Four stable luteolin-CH3OH complexes,six stable luteolin-(CH3OH)2 complexes and four stable luteolin-(CH3OH)3 complexes have been obtained.The theories of atoms in molecules(AIM) and natural bond orbital(NBO) have been used to analyze the hydrogen bonds of these compounds,and their interaction energies corrected by basis set superposition error are between-8.046 and-76.124 kJ/mol.The calculation results indicate strong hydrogen bonding interactions in the luteolin-(CH3OH)n complexes.Then the nuclear magnetic resonance(NMR) and electronic absorption spectrum of luteolin have been calculated,and the results are in agreement with the experimental data.     

Density functional theory study on the interaction of catechin and cytosine

The interacting patterns and mechanism of the catechin and cytosine have been investigated using the density functional theory B3LYP method with 6-31+G* basis set.Eleven stable structures of the catechin-cytosine complexes have been found respectively.The results indicate that the complexes are mainly stabilized by the hydrogen bonding interactions.Theories of atoms in molecules(AIM) and natural bond orbital(NBO) have been utilized to investigate the hydrogen bonds involved in all the systems.The interactio...     

Density functional theory and topological analysis on the hydrogen bonding interactions in N-protonated adrenaline–DMSO complexes

In this study, complexes formed via hydrogen bond interactions between N-protonated adrenaline (AdH⁺) and DMSO have been studied by density functional theory (DFT). The relevant geometries, energies, and IR characteristics of the hydrogen bonds (H-bonds) have been systematically investigated. The natural bond orbital (NBO) and the quantum theory of atoms in molecule (QTAIM) analysis have also been applied to understand the nature of the hydrogen bonding interactions in complexes. The H-bonds involving amino or hydroxyls as H-donor are dominant H-bonds in complexes and are attributed to strong H-bonds. The weak H-bonds, such as π H-bonds and H-bonds involving methyl (DMSO) or methenyls (C2H6 and C5H7 of AdH⁺) as H-acceptors, were found in complexes as well. The complexes in which the dominant H-bond involves amino of AdH⁺ as H-donor are more stable than those with the dominant H-bond involving hydroxyls as H-donor. Some relationships between various properties of QTAIM, NBO, geometry as well as frequency were also investigated.     

Evaluation of C4 diphosphine ligands in rhodium catalysed methanol carbonylation under a syngas atmosphere: synthesis, structure, stability and reactivity of rhodium(I) carbonyl and rhodium(III) acetyl intermediates

The carbonylation of methanol to acetic acid is a hugely important catalytic process, and there are considerable cost and environmental advantages if a process could be designed that was tolerant of hydrogen impurities in the CO feed gas, while eliminating by-products such as propionic acid and acetaldehyde altogether. This paper reports on an investigation into the application of rhodium complexes of several C(4) bridged diphosphines, namely BINAP, 1,4-bis(diphenylphosphino)butane (dppb), bis(diphenylphosphino)xylene (dppx) and 1,4-bis(dicyclohexylphosphino)butane (dcpb) as catalysts for hydrogen tolerant methanol carbonylation. An investigation into the structure, reactivity and stability of pre-catalysts and catalyst resting states of these complexes has also been carried out in order to understand the observations in catalysis. Rh(I) carbonyl halide complexes of each of the ligands have been prepared from both [Rh(2)(CO)(4)Cl(2)] and dimeric mu-Cl-[Rh(L)Cl](2) complexes. These Rh(I) carbonyl complexes are either dimeric with bridging phosphine ligands (dppb, dcpb, dppx) or monomeric chelate complexes. The reaction of the complexes with methyl iodide at 140 degrees C has been studied, which has revealed clear differences in the stability of the corresponding Rh(III) complexes. Surprisingly, the dimeric Rh(I) carbonyls react cleanly with MeI with rearrangement of the diphosphine to a chelate co-ordination mode to give stable Rh(III) acetyl complexes. The Rh acetyls for L=dppb and dppx have been fully characterised by X-ray crystallography. During the catalytic studies, the more rigid dppx and BINAP ligands were found to be nearly 5 times more hydrogen tolerant than [Rh(CO)(2)I(2)](-), as revealed by by-product analysis. The origin of this hydrogen tolerance is explained based on the differing reactivities of the Rh acetyls with hydrogen gas, and by considering the structure of the complexes.     

氨基酸侧链与氧化鸟嘌呤碱基对体系的氢键作用

应用量子化学方法,分别在气相和水溶液中对氨基酸侧链与氧化鸟嘌呤碱基对(8-oxo-G∶C)形成的三体复合物的氢键键能、几何结构、电荷分布及二阶稳定化能进行了研究.结果表明,水溶液的存在削弱了复合物中的氢键强度,电荷分布变化明显,水溶液中形成氢键位点的电荷变化量约为气相中的10倍,而几何结构变化不明显、对于酶与DNA之间的相互作用的研究需在水溶液中进行.水溶液对带电三体复合物中8-oxo-G∶C与氨基酸侧链间的氢键有较大影响,键能平均减小了69.23 k J/mol,不带电复合物仅减小了3.60k J/mol.水溶液中三体复合物中8-oxo-G∶C间的氢键受侧链的影响不大,且与侧链带电与否无关,带电复合物和不带电复合物的氢键强度分别减小了24.57和30.05 k J/mol,且二阶稳定化能越大,其对应的氢键键长越短.     

C-H⋯O, O-H⋯C, and C-H⋯C interactions in complexes of carbocations and carboanions

Molecular complexes formed by different forms of carbocations (carbenium ions) and carboanions with water, acetylene, and methane molecules have been calculated by the MP2/6-311++G(2df,2pd) method. In complexes with water where the carbon atom of the carbocation (carboanion) acts as the proton donor (acceptor), the energies of the C-H?O and O-H?C hydrogen bonds turn out to be approximately the same being 13–20 kcal/mol for carbocation (carboanion) species differing in the valence state of the carbon atom. Two types of C-H?C interactions have been revealed depending on the charge at the bridging hydrogen atom, which is determined by the hybridization of the donor carbon atom. The C-H?C interaction energy in molecular complexes with the positively charged hydrogen atom (carboanion complexes with acetylene) is an order of magnitude higher than in the complexes where the bridging hydrogen atom has an excess of electron density (carbocation complexes with methane). In all the complexes under consideration, the covalent C-H bond involved in interaction is elongated, and the negative charge is transferred from the acceptor to the donor.     

Density Functional Theory Study on Hydrogen Bonding Interaction of Catechin-(H2O)n

Density functional theory B3LYP method with 6‐31G* basis set has been used to optimize the geometries of the catechin, water and catechin‐(H₂O)_n complexes. The vibrational frequencies have been studied at the same level to analyze these complexes. Six and eleven stable structures for the catechin‐H₂O and catechin‐(H₂O)₂ have been found, respectively. Theories of atoms in molecules (AIM) and natural bond orbital (NBO) have been utilized to investigate the hydrogen bonds involved in all the systems. The interaction energies of all the complexes corrected by basis set superposition error, are from ?13.27 to ?83.56 kJ/mol. All calculations also indicate that there are strong hydrogen‐bonding interactions in catechin‐water complexes. The strong hydrogen‐bonding contributes to the interaction energies dominantly. The O–H stretching motions in all the complexes are red‐shifted relative to that of the monomer.