Gutowski Keith E, Rogers Robin D, Dixon David A
Department of Chemistry and Center for Green Manufacturing, The University of Alabama, Box 870336, Tuscaloosa, Alabama 35487-0336, USA.
J Phys Chem A. 2006 Oct 26;110(42):11890-7. doi: 10.1021/jp0643698.
The heats of formation of 1H-imidazole, 1H-1,2,4-trizazole, 1H-tetrazole, CH3NO2, CH3N3, CH3NH2, CH2CHNO2, HClO4, and phenol, as well as cations and anions derived from some of the molecules have been calculated using ab initio molecular orbital theory. These molecules are important as models for compounds used for energetic materials synthesis. The predicted heats of formation of the heterocycle-based compounds are in excellent agreement with available experimental values and those derived from proton affinities and deprotonation enthalpies to <1 kcal/mol. The predicted value for the tetrazolium cation differs substantially from the experimental value, likely due to uncertainty in the measurement. The heats of formation of the nitro and amino molecules, as well as phenol/phenolate, also are in good agreement with the experimental values (<1.5 kcal/mol). The heat of formation of CH3N3 is predicted to be 72.8 kcal/mol at 298 K with an estimated error bar of +/-1 kcal/mol on the basis of the agreement between the calculated and experimental values for DeltaH(f)(HN3). The heat of formation at 298 K of HClO4 is -0.4 kcal/mol, in very good agreement with the experimental value, as well as a W2 literature study. An extrapolation of the CCSD(T)/aug-cc-pV(Q,5) energies was required to obtain this agreement. This result suggests that very large basis sets (> or =aug-cc-pV5Z) may be needed to fully recover the valence correlation energy contribution in compounds containing elements with high formal oxidation states at the central atom. In addition tight d functions are needed for the geometry predictions. Douglas-Kroll-Hess (DKH) scalar relativistic corrections for HClO4 and ClO4- at the MP2 level with correlation-consistent DKH basis sets were predicted to be large, likely due to the high formal oxidation state at the Cl.
使用从头算分子轨道理论计算了1H-咪唑、1H-1,2,4-三唑、1H-四唑、CH3NO2、CH3N3、CH3NH2、CH2CHNO2、HClO4和苯酚以及一些分子衍生的阳离子和阴离子的生成热。这些分子作为用于高能材料合成的化合物模型很重要。基于杂环的化合物的预测生成热与现有实验值以及从质子亲和力和去质子化焓得出的值非常吻合,误差小于1千卡/摩尔。四唑鎓阳离子的预测值与实验值有很大差异,可能是由于测量中的不确定性。硝基和氨基分子以及苯酚/酚盐的生成热也与实验值吻合良好(<1.5千卡/摩尔)。根据计算值与DeltaH(f)(HN3)的实验值之间的一致性,预测CH3N3在298K时的生成热为72.8千卡/摩尔,估计误差范围为±1千卡/摩尔。HClO4在298K时的生成热为-0.4千卡/摩尔,与实验值以及W2文献研究非常吻合。需要对CCSD(T)/aug-cc-pV(Q,5)能量进行外推才能得到这种吻合。该结果表明,对于含有中心原子具有高形式氧化态元素的化合物,可能需要非常大的基组(≥aug-cc-pV5Z)才能完全恢复价层相关能的贡献。此外,几何预测需要紧密的d函数。在MP2水平上,使用相关一致的DKH基组对HClO4和ClO4-进行的Douglas-Kroll-Hess(DKH)标量相对论校正预计很大,这可能是由于Cl的高形式氧化态所致。
