Gianola Adam J, Ichino Takatoshi, Kato Shuji, Bierbaum Veronica M, Lineberger W Carl
JILA, University of Colorado and National Institute of Standards and Technology, Department of Chemistry and Biochemistry, University of Colorado, Boulder, Colorado 80309-0440, USA.
J Phys Chem A. 2006 Jul 13;110(27):8457-66. doi: 10.1021/jp057499+.
The 351.1 nm photoelectron spectrum of 1-pyrazolide anion has been measured. The 1-pyrazolide ion is produced by hydroxide (HO(-)) deprotonation of pyrazole in a flowing afterglow ion source. The electron affinity (EA) of the 1-pyrazolyl radical has been determined to be 2.938 +/- 0.005 eV. The angular dependence of the photoelectrons indicates near-degeneracy of low-lying states of 1-pyrazolyl. The vibronic feature of the spectrum suggests significant nonadiabatic effects in these electronic states. The gas phase acidity of pyrazole has been determined using a flowing afterglow-selected ion flow tube; Delta(acid)G(298) = 346.4 +/- 0.3 kcal mol(-1) and Delta(acid)H(298) = 353.6 +/- 0.4 kcal mol(-1). The N-H bond dissociation energy (BDE) of pyrazole is derived to be D(0)(pyrazole, N-H) = 106.4 +/- 0.4 kcal mol(-1) from the EA and the acidity using a thermochemical cycle. In addition to 1-pyrazolide, the photoelectron spectrum demonstrates that HO(-) deprotonates pyrazole at the C5 position to generate a minor amount of 5-pyrazolide anion. The photoelectron spectrum of 5-pyrazolide has been successfully reproduced by a Franck-Condon (FC) simulation based on the optimized geometries and the normal modes obtained from B3LYP/6-311++G(d,p) electronic structure calculations. The EA of the 5-pyrazolyl radical is 2.104 +/- 0.005 eV. The spectrum exhibits an extensive vibrational progression for an in-plane CCN bending mode, which indicates a substantial difference in the CCN angle between the electronic ground states of 5-pyrazolide and 5-pyrazolyl. Fundamental vibrational frequencies of 890 +/- 15, 1110 +/- 35, and 1345 +/- 30 cm(-1) have been assigned for the in-plane CCN bending mode and two in-plane bond-stretching modes, respectively, of X (2)A' 5-pyrazolyl. The physical properties of the pyrazole system are compared to the isoelectronic systems, pyrrole and imidazole.
已测量了1-吡唑阴离子的351.1纳米光电子能谱。1-吡唑离子是在流动余辉离子源中通过吡唑的氢氧根离子(HO(-))去质子化产生的。已确定1-吡唑基自由基的电子亲和能(EA)为2.938±0.005电子伏特。光电子的角度依赖性表明1-吡唑基低能态近乎简并。光谱的振动电子特征表明这些电子态中存在显著的非绝热效应。使用流动余辉-选择离子流管测定了吡唑的气相酸度;Δ(acid)G(298)=346.4±0.3千卡/摩尔(-1),Δ(acid)H(298)=353.6±0.4千卡/摩尔(-1)。利用热化学循环,根据电子亲和能和酸度推导出吡唑的N-H键解离能(BDE)为D(0)(吡唑,N-H)=106.4±0.4千卡/摩尔(-1)。除了1-吡唑阴离子外,光电子能谱表明HO(-)在C5位置使吡唑去质子化,生成少量的5-吡唑阴离子。基于从B3LYP/6-311++G(d,p)电子结构计算获得的优化几何结构和简正模式,通过弗兰克-康登(FC)模拟成功再现了5-吡唑阴离子的光电子能谱。5-吡唑基自由基的电子亲和能为2.104±0.005电子伏特。该光谱显示出平面内CCN弯曲模式的广泛振动进展,这表明5-吡唑阴离子和5-吡唑基的电子基态之间的CCN角存在显著差异。已分别为X(2)A' 5-吡唑基的平面内CCN弯曲模式和两个平面内键拉伸模式指定了890±15、1110±35和1345±30厘米(-1)的基本振动频率。将吡唑体系的物理性质与等电子体系吡咯和咪唑进行了比较。
