Abstract

High-resolution transient IR absorption spectroscopy was used to measure (0001− 0000) R-branch transition frequencies for N2O molecules in extreme rotational states, with quantum number up to J = 205 and energies as high as Erot=17,000 cm−1. A population inversion of rotationally excited N2O states was prepared with an optical centrifuge and probed in a multi-pass IR cell using a quantum cascade laser. The optical centrifuge is based on 800-nm ultrafast, chirped laser pulses that optically trap molecules and accelerate them angularly to extreme rotational states. This work substantially increases the range of observed transitions for this band beyond the J = 100 transitions previously reported and provides benchmark measurements for theoretical predictions based on an effective Hamiltonian using a polyad model. Transient Doppler-broadened IR line profiles of N2O show that optical excitation of the sample is selectively partitioned into rotation, prior to Doppler broadening from rotation-to-translation collisional energy transfer. These results demonstrate how high-J transitions can be measured without thermal heating by coupling optical centrifuge excitation with high-resolution transient IR absorption probing.

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