2:00 PM–3:40 PM, Thursday, May 29, 2008
Keller Building - 104
Chair: Eric Wells, Augustana College, Sioux Falls
Abstract ID: BAPS.2008.DAMOP.K3.2
2:20 PM–2:40 PM
Joanna Salacka
(University of Washington)
Trapped ions are one of the most promising candidates for the implementation of quantum computation. We are trapping single ions of Ba$^{137}$ to serve as our qubit, because the hyperfine structure of its ground state and its various visible-wavelength transitions make it favorable for quantum computation. The two hyperfine ground levels will serve as our $\vert $1$>$ and $\vert $0$>$ qubit states. The readout of the qubit will be accomplished by first selectively shelving the ion directly to the metastable 5D5/2 state using a 1762 nm narrow band fiber laser. Next, the cooling and repumping lasers are turned on and the fluorescence of the ion is measured. Since the 5D5/2 state is decoupled from the laser cooling transitions, the ion will remain dark when shelved. Thus if fluorescence is seen we know that the qubit was in the $\vert $0$>$ state, and if no fluorescence is seen it was in the $\vert $1$>$ state. The laser is actively stabilized to a temperature-controlled, high-finesse 1.76 um Zerodur optical cavity. The shelving to the 5D5/2 state is most efficiently achieved with adiabatic passage, which requires a smooth scan of the laser frequency across the transition resonance. To accomplish this, the laser frequency is modulated by an AOM driven by a smooth frequency sweep of adjustable amplitude and duration.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2008.DAMOP.K3.2