Sub-cycle symmetry breaking of atomic bound states interacting with a short and strong laser pulse in a time-domain picture

TL;DR

This paper demonstrates the observation of sub-cycle symmetry breaking in helium atoms caused by strong laser pulses, using attosecond transient absorption spectroscopy to resolve the dynamics within an optical cycle.

Contribution

It introduces a time-domain approach to observe and analyze symmetry breaking effects in atomic states under strong laser fields, specifically in helium at n=2.

Findings

Detected instantaneous polarization and symmetry breaking signatures.

Developed a time domain model of the dipole response.

Showed potential for controlling atomic and molecular states with laser fields.

Abstract

In any atomic species, the spherically symmetric potential originating from the charged nucleus results in fundamental symmetry properties governing the structure of atomic states and transition rules between them. If atoms are exposed to external electric fields, these properties are modified giving rise to energy shifts such as the AC Stark-effect in varying fields and, contrary to this in a constant (DC) electric field for high enough field strengths, the breaking of the atomic symmetry which causes fundamental changes in the atom's properties. This has already been observed for atomic Rydberg states with high principal quantum numbers. Here, we report on the observation of effects linked to symmetry breaking in helium within the optical cycle of the utilized strong visible laser fields for states with principal quantum number n=2. These findings were enabled by temporally resolving the dynamics better than the sub-optical cycle of the applied laser field, utilizing the method of attosecond transient absorption spectroscopy (ATAS). We identify the spectroscopic fingerprint of instantaneous polarization and breaking of the symmetry of the atom in the intense visible femtosecond pulse used in an ATAS experiment and develop a time domain picture describing the dipole response that leads to these signatures. In the future, this general experimental approach can be used to measure strong-field induced symmetry-breaking effects in other atomic or molecular systems also consisting of two or more active electrons and thus to examine new routes to their bound-state and transition-state control by laser fields.