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Controlling the hyperfine state of rovibronic ground-state polar molecules

Ultracold molecules offer entirely new possibilities for the control of quantum processes due to their rich internal structure. Recently, near quantum degenerate gases of molecules have been prepared in their rovibronic ground state. For future experiments, it is crucial to also control their hyperfine state. Here, we report the preparation of a rovibronic ground state molecular quantum gas in a single hyperfine state and in particular in the absolute lowest quantum state. The demonstrated and presented scheme is general for bialkali polar molecules and allows the preparation of molecules in a single hyperfine state or in an arbitrary coherent superposition of hyperfine states. The scheme relies on electric-dipole, two-photon microwave transitions through rotationally excited states and makes use of electric nuclear quadrupole interactions to transfer molecular population between different hyperfine states.

preprint2009arXivOpen access
S. OspelkausK. -K. NiG. QuemenerB. NeyenhuisD. WangM. H. G. de MirandaJ. L. BohnJ. YeD. S. Jin
physics.atom-phcond-mat.othercond-mat.quant-gas
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Open access9 authors3 topics
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S. OspelkausK. -K. NiG. QuemenerB. NeyenhuisD. WangM. H. G. de MirandaJ. L. BohnJ. YeD. S. Jin

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