CREATION AND MANIPULATION OF COHERENCES IN MOLECULES WITH A PULSED MAGNETIC-FIELD

We demonstrate the application of a pulsed magnetic field for the crea tion and manipulation of coherences in molecular systems, using quantu m beat spectroscopy for the detection of the dynamics of the molecular superposition states. In all cases: the experiments are performed on energy levels in electronically excited states of the (jet-cooled) CS2 molecule populated by a short laser pulse. In the basic experiment, f ollowing excitation of initially degenerate Zeeman sublevels under zer o field conditions with suitable laser polarization, quantum beats are generated at the moment the magnetic held is switched on: even when t he field is delayed by several excited state lifetimes. By quenching o f the field, it is shown that the molecule may be ''frozen'' in any su perposition state of the participating sublevels. Using a combination of static and pulsed fields with different orientations. the molecule can be prepared in a more general state, described by coherences among all Zeeman substrates. This is achieved by choosing an appropriate ti me delay for the switched field, without any change to the geometrical parameters of the experiment such as laser polarization or detection direction. Numerical simulations of these dynamical coherence phenomen a have been performed to support assignment and interpretation of the experimental results.