1-戊基的紫外光解动力学（英文）

利用高里德堡态氢原子飞行时间(HRTOF)探测技术,研究了1-戊基在解离光波长范围236～254 nm下的光解离动力学过程.1-戊基的氢原子光解碎片谱在245 nm左右有一与乙基和正丙基在2p_z→3s跃迁下类似的峰.H原子和C_5H_(10)产物的平动能分布谱中存在双峰,分别位于5 kcal/mol(低平动能)和50 kcal/mol(高平动能)附近.在碳氢键断裂过程中,有30%的过剩能量转换为氢原子和对应解离碎片的平动能(高平动能产物(f_v=0.58,低平动能产物     

HNCO+HCO→NCO+CH2O氢转移反应的从头算及动力学研究

在UMP2 (Full) /6 311G(d ,p)计算水平上 ,优化了标题反应的反应物、过渡态、产物的几何结构 ,沿最小能量途径讨论了异氰酸 (HNCO)和甲酰自由基 (HCO)发生氢转移反应位能面上驻点的结构以及相互作用分子结构变化 .指出该反应是一个N -H键断裂和C -H键生成的协同反应 .进一步采用UQCISD(T ,Full)方法对反应途径上的驻点进行了单点能量校正 ,得出该反应的计算位垒是 91.4 7kJ/mol,与实验值 10 8.92kJ/mol接近 .在5 0 0～ 2 5 0 0K实验温度范围内 ,运用变分过渡态理论 (CVT)计算得到的速率常数与实验观测值进行了比较 .     

异丙醇在锐钛矿TiO2(101)表面的光化学

通过程序升温脱附谱的方法探究了266 nm激光照射下异丙醇在锐钛矿TiO₂（101）表面的光化学,并提出了详细的解离机理.在光照作用下,异丙醇发生分步解离：首先,O-H键断裂生成异丙氧基;然后,仲碳的C-H键在光照的作用下进一步发生解离,从而生成丙酮,两步生成的氢原子均转移到相邻的桥氧上.在升温过程中,这部分氢原子会与分子态的异丙醇发生置换反应,从而以低温水和高温异丙基的形式从表面脱附出来.     

烷烃类分子对NCO(A2∑+)自由基的猝灭

采用激光光解 激光诱导荧光 (LP LIF)的方法 ,用 2 6 6nm激光光解CHBr3 分子产生CH自由基 ,再与N2 O继续反应作为NCO自由基的产生源 ,用 4 38.6nm激光将电子基态X 2 Πi(0 0 10 )的NCO激励到激发态A2 Σ+ (0 0 0 0 )上 ,通过检测激发态NCO时间分辨荧光信号 ,测得室温 (2 98K)下NCO(A2Σ+ )被烷烃类分子猝灭的实验结果 ,获得了A 2Σ+ (0 0 0 0 )态猝灭速率常数 .实验发现 ,随着烷烃分子中C -H键数增加 ,其猝灭截面也近线性增加 ,但随着分子体积增大 ,这种增加趋缓 .     

CH3S自由基eA2A1态的近紫外光解动力学: 氢原子产物通道

实验研究射流冷却CH3S自由基eA2A1态在352 nm的光解动力学． 应用氢原子产额谱和光碎片平动能谱方法第一次直接观察到氢原子产物解离通道．CH3S自由基eA2A1态2132振动能级解离为H和H2CS产物．H+H2CS产物平动能释放较小，平动能峰值接近33.4 kJ/mol．氢原子产物角分布是各向同性．H+H2CS产物是经eA2A1激发态向X2E基态内转变，紧接着在基态势能面上解离产生．     

用扩散蒙特卡罗方法研究BH2, B(OH)2, BCl2和BCl的键离解能

采用扩散蒙特卡罗(DMC)方法计算了BH₂, B(OH)₂, BCl₂和BCl的HB-H和HOB-OH的键离解能, 同时也研究了轨道选择和Backflow变换对DMC计算结果的影响． 在Slater-Jastrow DMC(SJ-DMC)计算方法中,当采用B3PW91轨道时得到的HB-H和HOB-OH键离解能分别是359.1±0.12和98.2±0.12 kJ/mol;用B3LYP SJ-DMC计算键离解能得到了与用B3PW91 SJ-DMC方法类似的结果．通过BF-DMC(即在DMC中引入backflow修正)计算得到的HB?H键离解能为369.6±0.12 kJ/mol,也得到了更加接近实验值的HOB-OH键离解能为446.0±1.84 kJ/mol．由DMC的计算结果可以断定HB?H的键离解能的实验值为375.8 kJ/mol．另外还给出了BCl2和BCl的键离解能的计算结果.     

N_2O~ 离子A~2Σ~ 电子态的光解动力学研究

用一束波长为 36 0 5 5nm的激光 ,通过N2 O分子的 (3 1 )共振多光子电离 (REMPI)过程制备纯净且布居完全处于X2 Π(0 0 0 )态的母体离子N2 O ,然后用另一束波长在 2 75— 32 8nm范围内的可调谐激光将制备的N2 O 离子激发至预解离电子态A2 Σ .实验发现 ,由于解离碎片NO 所具有的一定的反冲速度 ,其TOF质谱峰明显比N2 O 母体宽 .通过分析NO 碎片TOF质谱峰形状 ,得到了解离产物的总平均平动能〈ET〉 ;通过考察〈ET〉随光解能量的变化 ,发现光解能量在 32 0 0 0cm- 1 附近约 2 5 0cm- 1 的变化范围内 ,〈ET〉值由约 80 0 0cm- 1 突然减小至约 1 6 0 0cm- 1 .通过分析 ,在光解能量小于 32 0 0 0cm- 1 的区域 ,解离通道为NO (X1 Σ ) N(4 S) ;而在光解能量大于 32 0 0 0cm- 1 的区域 ,另一个具有较高解离限的解离通道 ,NO (X1 Σ ) N(2 D) ,开启并完全取代N(4 S)通道成为解离的惟一通道 .根据实验结果 ,对在所研究的光解能量范围内的N2 O 离子A2 Σ 电子态预解离机理进行了探讨     

2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面的裂解机理

本文研究了2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面解离的可能微观反应机理,使用完全线性同步和二次同步变换(complete LST/QST)方法确定解离反应的过渡态.采用基于第一性原理的密度泛函理论与周期平板模型相结合的方法,优化了2-丙醇和1,1,1-三氟-2-丙醇裂解反应过程各物种在Ni(100)表面的top,hollow和bridge位的吸附模型,计算了能量,并对布局电荷进行了分析,得到了各物种的有利吸附位.结果表明:2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面都存在β-H和γ-H两个平行竞争的解离过程,其中2-丙醇在Ni(100)表面β-H解离的速控步骤活化能为64.7 k J·mol-1猯,而γ-H解离速控步骤活化能为233.1 k J·mol-1猯,故β-H解离过程占优势,主要产物是CH3COCH3;相反,1,1,1-三氟-2-丙醇在Ni(100)表面β-H解离的速控步骤活化能为257.1 k J·mol-1猯,而γ-H解离速控步骤活化能为148.1 k J·mol-1猯,故γ-H解离过程占优势,主要产物是CF3CH=CH2.由此说明,电负性更大的氟原子取代2-丙醇中的氢原子之后,2-丙醇在Ni表面的解离机理发生了改变.理论预测结果与实验结论一致.     

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 .     

2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面的裂解机理

本文研究了2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面解离的可能微观反应机理,使用完全线性同步和二次同步变换(complete LST/QST)方法确定解离反应的过渡态。采用基于第一性原理的密度泛函理论与周期平板模型相结合的方法,优化了2-丙醇和1,1,1-三氟-2-丙醇裂解反应过程各物种在Ni(100)表面的top,hollow和bridge位的吸附模型,计算了能量,并对布局电荷进行了分析,得到了各物种的有利吸附位。结果表明： 2-丙醇和1,1,1-三氟-2-丙醇在Ni(100)表面都存在β-H和γ-H两个平行竞争的解离过程,其中2-丙醇在Ni(100)表面β-H解离的速控步骤活化能为64.7 kJ∙mol-1,而γ-H解离速控步骤活化能为233.1kJ∙mol-1,故β-H解离过程占优势,主要产物是CH3COCH3;相反,1,1,1-三氟-2-丙醇在Ni(100)表面β-H解离的速控步骤活化能为257.1 kJ∙mol-1,而γ-H解离速控步骤活化能为148.1kJ∙mol-1,故γ-H解离过程占优势,主要产物是CF3CH=CH2。由此说明,电负性更大的氟原子取代2-丙醇中的氢原子之后,2-丙醇在Ni表面的解离机理发生了改变。理论预测结果与实验结论一致。     

2-Propanol photodegradation over nitrogen-doped NaNbO3 powders under visible-light irradiation

Nitrogen-doped perovskite-type materials, yellowish NaNbO_3−xN_x powders, had been developed as visible-light-sensitive photocatalysts for decomposition of gaseous 2-propanol. The NaNbO_3−xN_x samples were characterized by X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), ultraviolet-visible (UV-vis) light diffuse reflectance spectroscopy, Brunauer-Emmett-Teller (BET) measurement, and scanning electron microscopy (SEM). The UV-vis spectra confirmed that the spectral response of the NaNbO₃ powders could be tuned to visible-light region by nitrogen doping technique. The photocatalytic activities of NaNbO_3−xN_x samples were evaluated by decomposing gaseous 2-propanol into acetone and CO₂ under visible-light irradiation (400 nm<λ<520 nm). The NaNbO_3−xN_x sample annealed at 833 K showed the highest visible-light photocatalytic activity among all the nitrogen-doped samples. The relationship between nitrogen doping amount and photocatalytic activity of NaNbO_3−xN_x samples was also investigated and discussed.     

Kinetics of the oxidation of 2-Propanol with molecular oxygen under conditions of selective inhibition

The specifics of the mechanism of chain propagation in the radical-chain oxidation of 2-propanol at 323 K were studied by the method of selective inhibition with the use of nitrobenzene and ionol. The rate constants for the interaction of the 1-hydroxy-1-methylethylperoxy (k _2.1 = (0.097 ± 0.004) L mol^?1 s^?1) and hydroperoxy (k _2.2 = 0.13 ± 0.05 L mol^?1 s^?1) radicals with alcohol and their relative contributions to the chain propagation reactions were determined.     

Electron-Impact Fragmentographic Fluorescence Spectroscopy of Ethanol,Acetaldehyde, 1- and 2-Propanol and Acetone

Abstract

Gaseous ethanol, acetaldehyde, 1-propanol, 2-propanol and acetone at pressures of 2 × 10^?5 to 5 × 10^?4 torr were irradiated with electrons of energies 0-1000 eV. The visible-region fluorescence of the excited fragments was then measured. Studies included pressure dependence, electron energy dependence, threshold energy measurements, and excitation curve measurements. The aim of the research was to ascertain if molecules of similar structure could be differentiated by their spectra.     

Theoretical calculations of the kinetics and mechanisms of the gas phase elimination of primary,secondary, and tertiary 2‐hydroxyalkylbenzenes

Theoretical study of the elimination kinetics of 2‐phenylethanol, 1‐phenyl‐2‐propanol, and 2‐methyl‐1‐phenyl‐2‐propanol in the gas‐phase has been carried out at the MP2/6‐31G(d,p), B3LYP/6‐31G(d,p), B3LYP/6‐31++G(d,p), MPW1PW91/6‐31G(d,p), MPW1PW91/6‐31++G(d,p), PBEPBE/6‐31G(d,p), and PBEPBE/6‐31++G(d,p) levels of theory. The three substrates undergo two parallel elimination reactions. The first elimination appears to proceed through a six‐membered cyclic transition state to give toluene and the corresponding aldehyde or ketone. The second parallel elimination takes place through a four‐membered cyclic transition state producing water and the corresponding unsaturated aromatic hydrocarbon. Results from MP2/6‐31G(d,p) and MPW1PW91/6‐31++G(d,p) methods were found to be in good agreement with the experimental kinetic and thermodynamic parameters in the formation of toluene and the corresponding carbonyl compound. However, the results for PBEPBE/6‐31G(d,p) were in better agreement with the experimental data for the second parallel reaction yielding water and the corresponding unsaturated aromatic hydrocarbon. The charge distribution differences in the TS related to the substitution by methyl groups in the substrates can account for the observed reaction rate coefficients. The synchronicity parameters imply semi‐polar transition states for these elimination reactions. Copyright © 2009 John Wiley & Sons, Ltd.     

New spectral assignment of n‐propanol in the C―H stretching region

The C―H stretching vibration serves as an important probe for characterizing molecular structures and properties of hydrocarbons. In this work, we present a detailed study on gas‐phase Raman spectrum of n‐propanol in the C―H stretching region using stimulated photoacoustic Raman spectroscopy. A complete assignment was carried out with the aid of quantum chemistry calculations and depolarization ratio measurement as well as isotope substitutions, i.e. CH₃CD₂CD₂OH, CD₃CH₂CD₂OH and CD₃CD₂CH₂OH. It is shown that the spectra of three C―H groups of n‐propanol overlap each other because of Fermi resonance coupling and different molecular conformations, leading to complex features that were not determined previously. In addition, the comparisons between the spectra of three isotopologues reveal that the C―H vibrations at different sites of carbon chain exhibit different sensitivity to conformational change of n‐propanol. The CH₃ stretching vibration at terminated γ‐carbon is not sensitive whereas the CH₂ stretching vibrations at both α‐carbon and β‐carbon atoms are sensitive. Furthermore, Raman spectra of liquid propanol recorded by conventional spontaneous Raman technique are reassigned on the basis of gas‐phase analysis. Copyright © 2016 John Wiley & Sons, Ltd.     

Overlapping spectral features and new assignment of 2‐propanol in the C–H stretching region

The vibrational spectra of gaseous and liquid 2‐propanol in the C–H stretching region of 2800 ~ 3100 cm⁻¹ were investigated by polarized photoacoustic Raman spectroscopy and conventional Raman spectroscopy, respectively. Using two deuterated samples, that is, CH₃CDOHCH₃ and CD₃CHOHCD₃, the overlapping spectral features between the CH and CH₃ groups were identified. With the aid of depolarization ratio measurements and density functional theory calculations, a new spectral assignment was presented. In the gas phase, the band at 2884 cm⁻¹ was assigned to the overlapping of one CH₃ Fermi resonance mode and a CH stretching of gauche conformer. The bands at 2917 and 2933 cm⁻¹ were assigned to another two CH₃ Fermi resonance modes, but the latter includes weak contribution from CH stretching of trans conformer. The bands at 2950 and 2983 cm⁻¹ were assigned to CH₃ symmetric and antisymmetric stretching, respectively. The spectral features of liquid 2‐propanol are similar to those in the gas phase except for the blue shift of CH and the red shift of CH₃ band positions, which can be attributed to the intermolecular interaction in the liquid state. The new assignments not only clarify the confusions in previous studies from different spectral methods but also provide the reliable groundwork on spectral application of 2‐propanol in the futures. Copyright © 2014 John Wiley & Sons, Ltd.     

Mechanism of the acidic hydrolysis of epichlorohydrin

The present studies show that the currently accepted scheme for the hydrolysis of epichlorohydrin (ECH) needs to be extended by an additional path which makes allowance for the formation and decomposition of glycidol (GL). It was shown experimentally and through UB3LYP/6‐11 + +G(3D,P) calculations that the formation of 3‐chloro‐1,2‐propanediol (MCPD) from ECH should also take into account GL formation as an intermediate product. A modified mechanism for the course of ECH hydrolysis in acidic and neutral medium is proposed. It was shown that ECH hydrolysis in acidic medium in the presence of chloride ions also results in the formation of 1,3‐dichloro‐2‐propanol (DCPD) in addition to GL and MCPD. The possibility of a parallel pathway for water molecule addition to epichlorohydrin was shown which as a consequence led to the parallel appearance of GL and MCPD. It was confirmed by kinetic calculations that the state of equilibrium, reached in the process of ECH chlorination, did not result in GL formation. However, its appearance in the reaction mechanism has been ignored in the literature thus far. Copyright © 2011 John Wiley & Sons, Ltd.     

Catalysis by hydrogen chloride in the gas‐phase elimination kinetics of 2‐phenyl‐2‐propanol and 3‐methyl‐1‐buten‐3‐ol

A homogeneous, molecular, gas‐phase elimination kinetics of 2‐phenyl‐2‐propanol and 3‐methyl‐1‐ buten‐3‐ol catalyzed by hydrogen chloride in the temperature range 325–386 °C and pressure range 34–149 torr are described. The rate coefficients are given by the following Arrhenius equations: for 2‐phenyl‐2‐propanol log k₁ (s^?1) = (11.01 ± 0.31) ? (109.5 ± 2.8) kJ mol^?1 (2.303 RT)^?1 and for 3‐methyl‐1‐buten‐3‐ol log k₁ (s^?1) = (11.50 ± 0.18) ? (116.5 ± 1.4) kJ mol^?1 (2.303 RT)^?1. Electron delocalization of the CH₂?CH and C₆H₅ appears to be an important effect in the rate enhancement of acid catalyzed tertiary alcohols in the gas phase. A concerted six‐member cyclic transition state type of mechanism appears to be, as described before, a rational interpretation for the dehydration process of these substrates. Copyright © 2007 John Wiley & Sons, Ltd.     

丙醇水溶液中Fe2+与Ga3+、Ru3+、Pd2+、W（Ⅵ）和V（Ⅴ）的析相萃取分离

研究了在抗坏血酸存在下邻二氮菲-正丙醇-水体系析相萃取分离和富集铁的行为及与一些金属离子分离的条件。结果表明,在一定条件下,该体系能使Fe2+与Ga3+、Ru3+、Pd2+、W(Ⅵ)和V(Ⅴ)分离。