(a) Lowest vibrational states in the potential shown in figure 3(a) for Δ = −3|δ| and Ω<sub>L</sub>/|δ| = 2.8 <b>×</b> 10<sup>−6</sup> Martin Kiffner Wenhui Li Dieter Jaksch 10.6084/m9.figshare.1012044.v1 https://iop.figshare.com/articles/figure/_a_Lowest_vibrational_states_in_the_potential_shown_in_figure_a_href_http_iopscience_iop_org_0953_40/1012044 <p><strong>Figure 4.</strong> (a) Lowest vibrational states in the potential shown in figure <a href="http://iopscience.iop.org/0953-4075/46/13/134008/article#jpb460426f3" target="_blank">3</a>(a) for Δ = −3|δ| and Ω<sub>L</sub>/|δ| = 2.8 <b>×</b> 10<sup>−6</sup>. The energy difference of the vibrational states is ω<sub>vib</sub> ≈ 0.015|δ|. (b) Lowest vibrational state for different quantum numbers \mathcal {M} and on an energy scale defined by Ω<sub>L</sub>.</p> <p><strong>Abstract</strong></p> <p>We show that the dipole–dipole interaction between two Rydberg atoms can lead to substantial Abelian and non-Abelian gauge fields acting on the relative motion of the two atoms. We demonstrate how the gauge fields can be evaluated by numerical techniques. In the case of adiabatic motion in a single internal state, we show that the gauge fields give rise to a magnetic field that results in a Zeeman splitting of the rotational states. In particular, the ground state of a molecular potential well is given by the first excited rotational state. We find that our system realizes a synthetic spin–orbit coupling where the relative atomic motion couples to two internal two-atom states. The associated gauge fields are non-Abelian.</p> 2013-06-24 00:00:00 Lowest vibrational states Lowest vibrational state gauge fields Atomic Physics Molecular Physics