Until now, a suitable medium for a two-photon gate has proven difficult to realize. Researches have made a breakthrough on the latter challenge by harnessing photonic crystal cavities. Instead of using quantum dots (QDs) as the qubits themselves, researches team use an In As QD inside the optical cavity of a photonic crystal to give a nonlinear phase shift to qubits carried by photons.
In this approach, a QD in the ground state is illuminated in the photonic crystal cavity using two laser beams. When a single photon couples to cavity at the QD resonance, it is absorbed. But because the QD is coupled strongly to the cavity, the photon is reemitted. If a signal photon arrives at the cavity when there is already a control photon present, because the QD it sees is no longer in the ground state there is a change in the response – or a phase shift. This can be mapped into a rotation of the photon polarization, say the researchers, which represents a controlled interaction between the two photons.
Interaction between control and signal beams with the QD-induced dip in signal clearly visible.
Although the researchers were only able to achieve relatively small phase shifts of the signal polarization in this way, repeating the interaction multiple times (in as ‘cascade’) could make much larger phase shifts possible.
“This cavity-QD system represents that highest nonlinearity optical medium operating at the lowest powers on a semiconductor chip”. “This system is extremely promising for both low power switching in classical information processing and quantum gates in quantum information processing.”
Many engineering challenges remain to be overcome before this approach can be realized in practical terms, but the researchers are hopeful that they are not insurmountable and that their approach opens the way to chip-based logic using photons.
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