The High-Resolution Far- to Near-Infrared Anharmonic Absorption Spectra of Cyano-Substituted Polycyclic Aromatic Hydrocarbons from 300-6200 cm$^{-1}$

TL;DR

This study provides high-resolution anharmonic infrared spectra of cyano-substituted polycyclic aromatic hydrocarbons, revealing unique features that can aid in their identification in astronomical observations and laboratory experiments.

Contribution

It offers detailed anharmonic quantum chemical spectra of CN-PAHs across a broad IR range, highlighting distinctive features for astronomical and laboratory detection.

Findings

CN-PAHs exhibit broad absorption features similar to unsubstituted PAHs at low resolution.

High-resolution spectra reveal unique vibrational features of CN-PAHs in specific IR regions.

Cyano substitution causes shifts in vibrational frequencies, enabling differentiation of isomers.

Abstract

Cyano-substituted polycyclic aromatic hydrocarbons (CN-PAHs) may contribute to the emission detected in the 7 - 9 $\mu$m (1430 - 1100 cm$^{-1}$) and 11 - 15 $\mu$m (900 - 670 cm$^{-1}$) regions of astronomical IR spectra. Anharmonic quantum chemical computations of 17 CN-PAH isomers for 4 small PAHs and Benzene reveal strong, broad absorption features across the entire 300 - 6200 cm$^{-1}$ (33 - 1.6 $\mu$m) frequency range. In particular, when a FWHM of 15 cm$^{-1}$ is applied, the composite CN-PAH spectrum is almost indistinguishable from the unsubstituted-PAH spectrum. At high resolution, however, the infrared absorption spectra reveal unique, identifiable features of CN-PAHs in the 700 - 950, 1100 - 1300, 2000 - 2500, and 3400 - 3600 cm$^{-1}$ ranges. The in-plane and out-of-plane CH bending vibrational frequencies of CN-PAHs are shifted when comparing isomers and to their unsubstituted counterparts, making their differentiation in mixed laboratory experiments possible. The overall aromatic CH stretch fundamental (2950 - 3200 cm$^{-1}$) and first overtone (5950 - 6200 cm$^{-1}$) regions are relatively unaffected by the cyano-substitution, with changes only to the breadth and intensity of the bands. Detailed spectroscopic data on the normal mode components of each state reported herein provide the means to directly assign future laboratory spectra and to guide direct IR observations of astronomical regions with, e.g., JWST.