Electromagnetically-induced transparency (EIT) is a nonlinear optical phenomenon observed in atomic systems with a three-level energy structure. Introduced by Stephen Ernest Harris and co-workers at Stanford University in 1990, EIT exploits quantum interference to induce transparency within a resonant and otherwise opaque medium. In other words, the transmission of a probe beam through an optically dense medium is manipulated by means of a control beam. Therefore, EIT offers the possibility to control light with light. For this reason, it is attracting a growing interest for quantum information and quantum sensing technologies, including the practical realization of light storage and quantum memory devices.

There are three possible configurations for a three-level structure, known as lambda (Λ), vee (V) and ladder schemes. We intend to perform high-resolution spectroscopy of mercury vapors employing an original ladder-type EIT configuration. In this scheme, EIT manifests as optical transparency at wavelengths nearby the atomic transition from the ground state |g> to the excited state |e>, which normally exhibits significant attenuation, and an associated reduction in group velocity of the incident signal field. This transparency and slowed group velocity is due to the presence of a second, strong, optical control field which couples the excited state with an upper one (|s>), where the |s>→|e> transition is electric-dipole allowed while the |s>→|g> transition is forbidden.

Specifically, our EIT scheme involves a weak probe field nearby the intercombination transition of mercury from the ground state 6¹S₀ to the excited state 6³P₁ at 253.7 nm. Coherent deep-UV radiation is generated by means of a frequency-quadrupled scheme of an extended cavity diode laser (ECDL) at 1014.8 nm in a pair of nonlinear crystals. The near-infrared radiation is locked to an optical frequency comb, which in turn is stabilized against an ultra-stable GPS-disciplined Rb clock. In this way, we are able to perform comb-calibrated UV frequency scans throughout the intercombination line by tuning the comb repetition-rate.

The experiment aims to observe EIT for the ²⁰⁰Hg bosonic and ¹⁹⁹Hg fermionic isotopes to investigate the influence of hyperfine structure effects. We intend to acquire and analyse experimental transmission profiles of the signal beam as a function of control frequency shift for different levels of the resonant control-field power within the warm atomic system.