The heat of formation of NCO

Abstract

The heat of formation of NCO has been determined rigorously by state‐of‐the‐art ab initio electronic structure methods, including Mo/ller–Plesset perturbation theory from second through fifth order (MP2–MP5) and coupled‐cluster and Brueckner methods incorporating various degrees of excitation [CCSD, CCSD(T), BD, BD(T), and BD(TQ)]. Five independent reactions were investigated to establish a consistent value for ΔH_f,0^○(NCO): (a) HNCO(X̃ ¹A’)→H(²S)+NCO(²Π), (b) HNCO(X̃ ¹A’)→H⁺+NCO⁻, (c) N(⁴S)+CO→NCO(²Π), (d) HCN+O(³P)→H(²S)+NCO(²Π), and (e) NH(³Σ⁻)+CO→H(²S)+NCO(²Π). The one‐particle basis sets employed in the study were comprised of as many as 377 contracted Gaussian functions and ranged in quality from [4s2p1d] to [14s9p6d4f] on the (C,N,O) atoms and from [2s1p] to [8s6p4d] on hydrogen. After the addition of bond additivity corrections evaluated from related reactions of precisely known thermochemistry, all five approaches were found to converge on the value ΔH_f,0^○(NCO)=31.4(5) kcal mol⁻¹. Appurtenant refinements were obtained for the heat of formation of isocyanic acid, ΔH_f,0^○(HNCO)=−27.5(5) kcal mol⁻¹, and hydrogen cyanide, ΔH_f,0^○(HCN)=31.9(5) kcal mol⁻¹. The final proposals for ΔH_f,0^○(NCO) and ΔH_f,0^○(HNCO) resolve outstanding discrepancies with experiment and provide updates for thermochemical cycles of relevance to combustion chemistry.