Chien Yu Lien scite author profile

Laser cycling of resonances can remove entropy from a system via spontaneously emitted photons, with electronic resonances providing the fastest cooling timescales because of their rapid spontaneous relaxation. Although atoms are routinely laser-cooled, even simple molecules pose two interrelated challenges for cooling: every populated rotational-vibrational state requires a different laser frequency, and electronic relaxation generally excites vibrations. Here we cool trapped AlH þ molecules to their ground rotational-vibrational quantum state using an electronically exciting broadband laser to simultaneously drive cooling resonances from many different rotational levels. Undesired vibrational excitation is avoided because of vibrational-electronic decoupling in AlH þ . We demonstrate rotational cooling on the 140(20) ms timescale from room temperature to 3:8 þ 0:9 À 0:3 K, with the groundstate population increasing from B3 to 95:4 þ 1:3 À 2:1 % . This cooling technique could be applied to several other neutral and charged molecular species useful for quantum information processing, ultracold chemistry applications and precision tests of fundamental symmetries.

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Rotational state analysis of AlH+ by two-photon dissociation

Seck

Hohenstein

Lien

et al. 2014

Journal of Molecular Spectroscopy

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We perform ab initio calculations needed to predict the cross-section of an experimentally accessible (1 + 1 ′ ) resonance-enhanced multiphoton dissociation (REMPD) pathway in AlH + . Experimenting on AlH + ions held in a radiofrequency Paul trap, we confirm dissociation via this channel with analysis performed using time-of-flight mass spectrometry. We demonstrate the use of REMPD for rotational state analysis, and we measure the rotational distribution of trapped AlH + to be consistent with the expected thermal distribution. AlH + is a particularly interesting species for ion trap work because of its electronic level structure, which makes it amenable to proposals for rotational optical pumping, direct Doppler cooling, and single-molecule fluorescence detection. Potential applications of trapped AlH + include searches for time-varying constants, quantum information processing, and ultracold chemistry studies.

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Chien Yu Lien

Broadband optical cooling of molecular rotors from room temperature to the ground state

Rotational state analysis of AlH+ by two-photon dissociation

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