On demand single photon generation and coherent control of excitons from resonantly driven nanowire quantum dots
- URL: http://arxiv.org/abs/2409.14964v1
- Date: Mon, 23 Sep 2024 12:29:41 GMT
- Title: On demand single photon generation and coherent control of excitons from resonantly driven nanowire quantum dots
- Authors: Jun Gao, Govind Krishna, Edith Yeung, Lingxi Yu, Sayan Gangopadhyay, Kai-Sum Chan, Chiao-Tzu Huang, Thomas Descamps, Michael E. Reimer, Philip J. Poole, Dan Dalacu, Val Zwiller, Ali W. Elshaari,
- Abstract summary: nanowire-based quantum dot sources are popular due to their potential for on-chip hybrid integration.
We demonstrate on-demand single-photon generation from resonantly excited InAsP/InP nanowire quantum dots.
It paves the way for hybrid quantum photonic integration, enabling spin-photon entanglement and matter memories on-chip.
- Score: 2.3301636913156467
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Coherent control of single photon sources is a key requirement for the advancement of photonic quantum technologies. Among them, nanowire-based quantum dot sources are popular due to their potential for on-chip hybrid integration. Here we demonstrate on-demand single-photon generation ($g^{(2)}(0)(X^{*}) =0.078$ and $g^{(2)}(0)(X)= 0.03$) from resonantly excited InAsP/InP nanowire quantum dots and observe Rabi oscillations in the dot emission, indicating successful coherent manipulation of the excitonic states in the nanowire. We also measure a low emission time jitter for resonant excitation as compared to above-band excitation. This work addresses the long-standing challenge of resonantly exciting nanowire-quantum dots. It paves the way for hybrid quantum photonic integration, enabling spin-photon entanglement and matter memories on-chip.
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