A new spectroscopically-determined potential energy surface and ab initio dipole moment surface for high accuracy HCN intensity calculations

Abstract

Calculations of transition intensities for small molecules like H2O, CO, CO2 based on s high-quality potential energy surface (PES) and dipole moment surface (DMS) can nowadays reach sub-percent accuracy. An extension of this treatment to a system with more complicated internal structure -- HCN/HNC (hydrogen cyanide/hydrogen isocyanide) is presented. A highly accurate spectroscopically-determined PES is built based on a recent \ of the HCN/HNC isomerizing system. 588 levels of HCN with J~=~(0,~2,~5,~9,~10) are reproduced with a standard deviation from the experimental values of σ=0.0373 \ and 101 HNC levels with J~=~(0,~2) are reproduced with σ=0.37 . The dependence of the HCN rovibrational transition intensities on the PES is tested for the wavenumbers below 7200 . Intensities are computed using wavefunctions generated from an \ and our optimized PES. These intensities differ from each other by more than 1\%\ for about 11\% of the transitions tested, showing the need to use an optimized PES to obtain wavefunctions for high-accuracy predictions of transition intensities. An \ DMS is computed for HCN geometries lying below 11~200 . Intensities for HCN transitions are calculated using a new fitted PES and newly calculated DMS. The resulting intensities compare much better with experiment than previous calculations. In particular, intensities of the H--C stretching and bending fundamental transitions are predicted with the subpercent accuracy.