| An electron spin confined to a self-assembled semiconductor quantum dot is a candidate system to act as a quantum bit, a qubit. In order to act in this capacity it must be entangled with other qubits. Both electrons and holes are confined in such dots, allowing optical manipulation and emission of light. A single photon could act as an intermediary qubit, becoming entangled with a spin and conveying the entanglement from one spin to another. By an appropriate optical pulse sequence, a superposition state has been created, which upon radiative decay would be entangled with an emitted photon. A continuous wave beam optically pumps and measures the state in the interim before the next repetition of the pulse sequence. Here I describe the pulse sequence and measurement methods, display the experimental results, and show how to compute the entanglement of our state. Numerical simulations of the coherence of the generated state agree with the measured value of 0.28 out of a possible 0.5. The main cause of deviation from the ideal value is state relaxation during control pulse sequence. The fidelity of the state to the ideal precursor state is computed to be 0.81, and the entanglement that would result upon emission of a vertically polarized photon is 0.18, and simulations suggest 0.60 is possible with optimum design. |
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