High-resolution double resonance action spectroscopy in ion traps: vibrational and rotational fingerprints of CHNH

By applying various action spectroscopic techniques in a 4 K cryogenic ion trap instrument, protonated methanimine, CH 2 NH 2 + , has been investigated by high-resolution rovibrational and pure rotational spectroscopy for the first time. In total, 39 rovibrational transitions within the fundamental band of the ν 2 symmetric C-H stretch were measured around 3026 cm −1 , which were used to predict pure rotational transition frequencies of CH 2 NH 2 + in the ground vibrational state. Based on these predictions, nine rotational transitions were observed between 109 and 283 GHz using a novel double resonance method, which significantly improved the sensitivity of the rotational measurements. This double resonance method consists of rotational excitation followed by vibrational excitation, which is finally detected as a dip in the number of CH 2 NH 2 + -He complexes formed in the 4 K He bath of the trap. The new measurements and the derived predictions of pure rotational transitions will enable the first radio-astronomical search for CH 2 NH 2 + . A novel rotation-vibration double resonance scheme was used to measure the first pure rotational transition frequencies of protonated methanimine (CH 2 NH 2 + ) in a 4 K cryogenic ion trap.