15min:

MELANIE SCHNELL, Center for Free-Electron Laser Science, Hamburg, Germany; SIMON MERZ, NICOLAS VANHAECKE, Fritz-Haber-Institut der Max-Planck-Gesellschaft, Berlin, Germany; WOLFGANG JÄGER, University of Alberta, Edmonton, Canada; GERARD MEIJER, Fritz-Haber-Institut der Max-Planck-Gesellschaft, Berlin, Germany.

An important remaining issue in the field of cold molecules is a general technique to manipulate the motion of polar molecules in high-field-seeking states, which is crucial for the investigation of molecules in their ground states and of all large and more complex molecules. Complementary to the already demonstrated and experimentally rather challenging alternating gradient methods, we exploit the interaction of polar molecules with electromagnetic radiation in a microwave cavity. Based on the concept of our microwave lens we have developed a decelerator for polar molecules that allows motion control in three dimensions. It consists of a cylindrically symmetric microwave resonator, which is cooled to liquid nitrogen temperature. For our deceleration experiments, we are using the TE_1,1,12 mode, i.e., the decelerator consists of 12 stages. We will present a detailed characterization of the microwave deceleration process and discuss prospects for future experiments, which are opening the door for novel control experiments of larger molecules.