Catching the wave - Controlling quantum atom-ion interaction to be attractive, repulsive - or turning it off for decades, the field of ultra-cold chemistry of ions and atoms has been launching the fundamental quest for investigating its quantum regime. A simplifying summary of the quest might be: How do interactions and chemical reactions between neutral and charged atoms/molecules proceed at extremely low temperatures? The classical picture predicts that all dynamics comes to a standstill as zero velocity is approached. However, deviations are expected since the classical model ceases to be appropriate at microscopic scales and at low temperatures, where particle-wave dualism of matter get’s important. In this regime, quantum effects dominate and reactions are predicted to obey fundamentally different rules. Examples are: (i) collisions of atoms, necessary for a reaction, cannot be described as a billiard-like impact between hard spheres anymore, but rather as interfering waves, interacting at long range, which can coherently amplify or even decoherently annihilate each other. (ii) energy barriers can surmount the available kinetic energy, but nevertheless be efficiently passed via quantum tunnelling, ruling the dynamics. Experimentally, we immerse a single trapped barium (Ba+) ion in a bath of fermionic lithium (Li) atoms. We span temperatures from far above room temperature down deep into the s-wave regime of nano-Kelvin. We aim at exploiting the collision energy dependence of magnetically tunable atom-ion scattering (Feshbach) resonances and at assigning their partial-wave-classification experimentally. We will study quantum scattering of atom-ion ensembles and distill the substantial differences to atom-atom dynamics. We aim at gaining control and state-sensitive detection on the level of individual quanta within the merged ion-atom system and to study and establish optically trapping of ions and atoms in general - for example to reveal the quantum dynamics of ion-atom and ion-molecule reactions in absence of any detrimental radio-frequency fields – that is – at unprecedented low temperatures.

DFG Programme Research Grants

International Connection Canada, France, Poland

Major Instrumentation Pumplaser

Instrumentation Group 5700 Festkörper-Laser

Cooperation Partners Professor Dr. Olivier Dulieu; Privatdozent Dr. Krzysztof Jachymski; Professor Dr. Kirk Madison; Professor Dr. Michal Tomza