Unresolved sideband photon recoil spectroscopy of molecular ions

Abstract

We reflect on the prospect of exploiting the recoil associated with absorption and emission of photons to perform spectroscopy of a single molecular ion. For this recoil to be detectable, the molecular ion is sympathetically cooled by a laser-cooled atomic ion to near their common quantum mechanical ground state within a trapping potential. More specifically, we present a general framework for simulating the expected photon recoil spectra in regimes where either the natural transition linewidth t of the molecular ion or the spectral width L of the exciting light source exceeds the motional frequencies of the two-ion system. To exemplify the framework, we present two complementary cases: spectroscopy of the broad 3s 2S1/2 - 3p 2P3/2 electronic transition (t/2π = 41.8 MHz) of a single 24Mg+ ion at λ=279.6 nm by a narrow laser source (L/2π 1 MHz) and mid-infrared vibrational spectroscopy of the very narrow |v=0,J=1 - |v'=1,J'=0 transition (t/2π = 2.50 Hz) at λ=6.17 μm in the 1+ electronic ground state of 24MgH+ by a broadband laser source (L/2π 50 MHz). The atomic ion 24Mg+ has been picked to introduce a simple system to make comparisons with experimental results while still capturing most of the physics involved in electronic excitations of molecular ions.