Sevy Andrew, Huffaker Robert F, Morse Michael D
Department of Chemistry, University of Utah , Salt Lake City, Utah 84112, United States.
J Phys Chem A. 2017 Dec 14;121(49):9446-9457. doi: 10.1021/acs.jpca.7b09704. Epub 2017 Dec 5.
Resonant two-photon ionization spectroscopy was used to locate predissociation thresholds in WC, WSi, WS, WSe, and WCl, allowing bond dissociation energies to be measured for these species. Because of the high degree of vibronic congestion in the observed spectra, it is thought that the molecules dissociate as soon as the lowest separated atom limit is exceeded. From the observed predissociation thresholds, dissociation energies are assigned as D(WC) = 5.289(8) eV, D(WSi) = 3.103(10) eV, D(WS) = 4.935(3) eV, D(WSe) = 4.333(6) eV, and D(WCl) = 3.818(6) eV. These results are combined with other data to obtain the ionization energy IE(WC) = 8.39(9) eV and the anionic bond dissociation energies of D(W-C) = 6.181(17) eV, D(W-C) = 7.363(19) eV, D(W-Si) ≤ 3.44(4) eV, and D(W-Si) ≤ 4.01(4) eV. Combination of the D(WX) values with atomic enthalpies of formation also provides ΔH° values for the gaseous WX molecules. Computational results are also provided, which shed some light on the electronic structure of these molecules.
利用共振双光子电离光谱法确定了WC、WSi、WS、WSe和WCl中的预解离阈值,从而能够测量这些物种的键解离能。由于在观测光谱中存在高度的振动-电子耦合现象,人们认为一旦超过最低分离原子极限,分子就会解离。根据观测到的预解离阈值,确定的解离能为:D(WC)=5.289(8) eV、D(WSi)=3.103(10) eV、D(WS)=4.935(3) eV、D(WSe)=4.333(6) eV和D(WCl)=3.818(6) eV。将这些结果与其他数据相结合,得到电离能IE(WC)=8.39(9) eV以及阴离子键解离能:D(W-C)=6.181(17) eV、D(W-C)=7.363(19) eV(此处两个D(W-C)可能有误,原文疑似重复)、D(W-Si)≤3.44(4) eV和D(W-Si)≤4.01(4) eV。D(WX)值与原子生成焓相结合,还可得到气态WX分子的ΔH°值。同时也给出了计算结果,这些结果为这些分子的电子结构提供了一些线索。
