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Using long-range magnetic gradient induced coupling between three effective spins, a coherent QFT is efficiently realized with trapped Yb+ ions. With a single Yb+ ion, RF magnetic fields are measured close to the quantum limit.
The use of long-wavelength radiation for gate operations is a promising approach for trapped-ion quantum computation. We demonstrate the key principle of this approach by generating a maximally entangled two-qubit Bell-state with fidelity of 0.985.
In this work we present a solution to this problem that relies on the fast Stark shift gate. In this scheme off-resonant carrier transitions that would lead to heating are forbidden thus achieving lower final temperature and a much higher cooling rate.
We study a new type of long-range correlations for waves propagating in a random medium. These correlations originate from scattering events which take place close to a point source. The scattered waves propagate by diffusion to distant regions. In this way long range correlations, between any pair of distant points, are established.
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