The collaborative research project on Molecule Interferometry and MEtrology (MIME) will establish new bounds in experimental matter-wave interferometry and it will explore new applications of quantum interference to molecule metrology.Using tailor-made molecules, the project aims at de Broglie interference experiments with molecules in the mass range up to and beyond 10,000 amu, i.e. surpassing all existing matter wave experiments by about an order of magnitude in mass and complexity. Using a recently established interference setup and new detection schemes the team aims at exploring the Talbot-Lau technique as a precise tool for determining molecular properties, such as electric polarizabilities as well as electrical or magnetic susceptibilities.MIME unites four expert teams from Austria, Germany and Switzerland with very complementary and interdisciplinary competences: First studies have shown already that perfluoroalkyl-functionalized compounds, synthesized by the partners in Basel, combine high molecular mass with a high vapor pressure and a low thermal velocity – ideal properties for matter wave interferometry. The best-adapted device for quantum interferometry in the high-mass regime is at present a Kapitza-Dirac-Talbot-Lau interferometer, such as recently successfully implemented in Vienna. In its present form it can accept thermal beams of tailor-made molecules up to 10,000 amu. Quantum interferometry will profit from enhanced detection schemes. High-resolution imaging of matter interferograms now becomes accessible through the nanotechnology group in Darmstadt/Karlsruhe. They will join forces with the partners in Basel to develop highly binding and immobilizing surfaces that are suitable as recording plates for molecular interferograms. Modern high-resolution imaging methods are then available in Darmstadt/Karlsruhe to analyze the recordings taken in Vienna.The proposed experiments will also render new decoherence phenomena accessible for the first time: The influence of different molecular conformations or molecular chiralities on matter wave coherence will be explored and quantitatively analyzed in collaboration with our theory partners in Munich.
Professor Markus Arndt
Faculty of Physics, University of Vienna, Vienna, Austria
Professor Horst Hahn
Joint Research Laboratory Nanomaterials, TU Darmstadt, Darmstadt, Germany
Dr Klaus Hornberger
Institut für Theoretische Quantenoptik, Ludwig-Maximilians-Universität München, Munich, Germany
Professor Marcel Mayor
University of Basel, Basel, Switzerland
Dr Hendrik Ulbricht
Faculty of Physics, University of Vienna, Vienna, Austria
and, School of Physics and Astronomy, University of Southampton, Southampton, UK