Abstract
Controlled non-local energy and coherence transfer enables light harvesting in photosynthesis and non-local logical operations in quantum computing. This process is intuitively pictured by a pair of mechanical oscillators, coupled by a spring, allowing for a reversible exchange of excitation. On a microscopic level, the most relevant mechanism of coherent coupling of distant quantum bits-like trapped ions, superconducting qubits or excitons confined in semiconductor quantum dots-is coupling via the electromagnetic field. Here we demonstrate the controlled coherent coupling of spatially separated quantum dots via the photon mode of a solid state microresonator using the strong exciton-photon coupling regime. This is enabled by two-dimensional spectroscopy of the sample's coherent response, a sensitive probe of the coherent coupling. The results are quantitatively understood in a rigorous description of the cavity-mediated coupling of the quantum dot excitons. This mechanism can be used, for instance in photonic crystal cavity networks, to enable a long-range, non-local coherent coupling.
Original language | English |
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Article number | 1747 |
Number of pages | 6 |
Journal | Nature Communications |
Volume | 4 |
DOIs | |
Publication status | Published - Apr 2013 |
Keywords
- SINGLE QUANTUM-DOT
- LIGHT
- SPIN
- SPECTROSCOPY
- GENERATION
- SYSTEMS
- CHIP