Laser magnetic resonance spectroscopy of the ν2 fundamental band of DO2 at 9.8 μm

Abstract

The ν₂ fundamental band (bending vibration, ν₀=1020.162 cm⁻¹) of the deuteroperoxyl radical DO₂ has been studied using the technique of laser magnetic resonance, in which molecular transitions are tuned into resonance with fixed laser lines by means of the Zeeman effect. The DO₂ was produced in a flow system by reacting the products of a discharge in O₂ with methanol (CH₃OD or CD₃OD) or ethanol (C₂H₅OD). About 150 resonances, observed using 19 different CO₂ laser lines in the 1009–1038 cm⁻¹ region, were assigned to DO₂ transitions with 1⩽N⩽9 and 1⩽K_a⩽6. Their analysis yielded the ν₂ band origin as well as rotation, spin–rotation, and centrifugal distortion parameters for the ground and ν₂ excited vibrational states. It was necessary to include in the analysis the effects of Coriolis interaction between ν₂ and ν₃, which lies about 100 cm⁻¹ higher in energy. Thus the Coriolis coupling constant and some effective ν₃ band parameters were also determined, though ν₃ was not observed directly.