Full-Dimensional Potential Energy Surfaces of Ground (\tilde X^2A') and Excited (\tildeA^2A") Electronic States of HCO and Absorption Spectrum

In this work, high-fidelity full-dimensional potential energy surfaces (PESs) of the ground (\tilde X^2A') and first doublet excited (\tilde A^2A") electronic states of HCO were constructed using neural network method. In total, 4624 high-level ab initio points have been used which were calculated at Davidson corrected internally contracted MRCI-F12 level of theory with a quite large basis set (ACV5Z) without any scaling scheme. Compared with the results obtained from the scaled PESs of Ndengué et al., the absorption spectrum based on our PESs has slightly larger intensity, and the peak positions are shifted to smaller energy for dozens of wavenumbers. It is indicated that the scaling of potential energy may make some unpredictable difference on the dynamical results. However, the resonance energies based on those scaled PESs are slightly closer to the current available experimental values than ours. Nevertheless, the unscaled high-level PESs developed in this work might provide a platform for further experimental and theoretical photodissociation and collisional dynamic studies for HCO system.