Haslinger, S. (2011). Cold atoms in a cryogenic environment [Dissertation, Technische Universität Wien]. reposiTUm. http://hdl.handle.net/20.500.12708/160987
Kalte Atome; Magneto optische Falle; Magnetischer Transport; Atom Chip; Kryogene Umgebung; Elektronenkanone; Eletronenstimulierte Desorption; Rubidium; Hybride Quantensysteme; Supraleitung
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cold atoms; magneto optical trap; magnetic transport; atom chip; cryogenic environment; electron gun; electron stimulated desorption; rubidium; hybrid quantum systems; superconductivity
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Abstract:
The idea of quantum information processing attracts increasingly interest, where a complex collection of quantum objects and quantum bits are employed to find the ideal building blocks for quantum information systems. Hybrid quantum systems are therefore promising objects as they countervail the particular drawbacks of single quantum objects.<br />Based on superconducting resonator technology, microwave coplanar waveguides provide a well suited interconnection for photons and solid-state quantum bits (qubits), extensively investigated in recent years. Since a quantum memory is presently missing in those electrical accessible circuit cavity quantum devices, connecting the fast processing in a solid sate device to the exceptional long coherence times in atomic ensembles, the presented work is focused to establish the technological foundations for the hybridization of such quantum systems. The microwave photons stored in a superconducting high finesse microwave resonator are therefore an ideal connection between the atom and the solid state quantum world. In the last decade, the miniaturization and integration of quantum optics and atomic physics manipulation techniques on to a single chip was successfully established. Such atom chips are capable of detailed quantum manipulation of ultra-cold atoms and provide a versatile platform to combine the manipulation techniques from atomic physics with the capability of nano-fabrication.<br />In recent years several experiments succeeded in realization of superconducting atom chips in cryogenic environments which opens the road for integrating super-conductive microwave resonators to magnetically couple an atomic ensemble to photons stored in the coplanar high finesse cavity.<br />This thesis presents the concept, design and experimental setup of two approaches to establish an atomic ensemble of rubidium atoms inside a cryogenic environment, based on an Electron beam driven alkali metal atom source for loading a magneto optical trap in a cryogenic environment, and a Magnetic transport of ultra-cold atoms into a cryostat. Results are presented, both for the electron beam driven atom source, and the magnetic transport, were an ensemble of rubidium atoms is finally trapped in a superconducting magnetic trap.