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TT: Fachverband Tiefe Temperaturen
TT 49: Poster Session: Superconductivity
TT 49.33: Poster
Mittwoch, 3. April 2019, 15:00–18:30, Poster D
Nb SQUIDs for the detection of the motion of macroscopic mechanical oscillators — •K. Uhl1, M. Rudolph1, J. Hofer2, J. Slater2, M. Aspelmeyer2, C. Schneider3, M. L. Juan3, D. Zoepfl3, G. Kirchmair3, O. F. Kieler4, T. Weimann4, R. Kleiner1, and D. Koelle1 — 1Physikalisches Institut and Center for Quantum Science (CQ) in LISA+, Universität Tübingen, Germany — 2Vienna Center for Quantum Science and Technology, University of Vienna, Austria — 3Institute for Experimental Physics, University of Innsbruck, Austria — 4Fachbereich Quantenelektronik, Physikalisch-Technische Bundesanstalt (PTB) Braunschweig, Germany
Macroscopic mechanical oscillators can be used to investigate fundamental questions in macroscopic quantum physics and for quantum sensing applications. Such systems, however, suffer from decoherence effects, e.g. due to parasitic coupling to the environment or light absorption. Levitating solid-state objects, like a superconducting particle in a magnetic trap or a cantilever with a superconducting strip, offer a unique approach to the realization of nano- or even micro-sized quantum systems with potentially minimal decoherence. In combination with cryogenic temperatures, the coherence times in the quantum mechanical ground state can be increased significantly. To gain information on position and oscillatory behavior, a dc SQUID is employed. To optimize magnetic coupling between oscillator and SQUID, we performed numerical simulations based on London equations and evaluated various SQUID designs The results of the numerical simulations and experimentally determined SQUID performance will be presented.