Your search keyword '"He, Xiao-Dong"' showing total 3 results

1. Efficient Two-Dimensional Defect-Free Dual-Species Atom Arrays Rearrangement Algorithm with Near-Fewest Atom Moves.

Author

Tao, Zhi-Jin, Yu, Li-Geng, Xu, Peng, Hou, Jia-Yi, He, Xiao-Dong, and Zhan, Ming-Sheng

Subjects

QUANTUM computing, OPTICAL tweezers, GRAPH connectivity, COMPUTING platforms, ATOMS

Abstract

Dual-species single-atom array in optical tweezers has several advantages over the single-species atom array as a platform for quantum computing and quantum simulation. Thus, creating the defect-free dual-species single-atom array with atom numbers over hundreds is essential. As recent experiments demonstrated, one of the main difficulties lies in designing an efficient algorithm to rearrange the stochastically loaded dual-species atoms arrays into arbitrary demanded configurations. We propose a heuristic connectivity optimization algorithm to provide the near-fewest number of atom moves. Our algorithm introduces the concept of using articulation points in an undirected graph to optimize connectivity as a critical consideration for arranging the atom moving paths. Tested in array size of hundreds atoms and various configurations, our algorithm shows a high success rate (>97%), low extra atom moves ratio, good scalability, and flexibility. Furthermore, we propose a complementary step to solve the problem of atom loss during the rearrangement. [ABSTRACT FROM AUTHOR]

Published

2022

2. Spectral filtering of dual lasers with a high-finesse length-tunable cavity for rubidium atom Rydberg excitation.

Author

Liu, Yang-Yang, Fu, Zhuo, Xu, Peng, He, Xiao-Dong, Wang, Jin, and Zhan, Ming-Sheng

Subjects

RYDBERG states, RUBIDIUM, RABI oscillations, OPTICAL tweezers, LASERS, PHASE noise, QUANTUM computing

Abstract

We propose and demonstrate an alternative method for spectral filtering and frequency stabilization of both 780-nm and 960-nm lasers using a high-finesse length-tunable cavity (HFLTC). Firstly, the length of HFLTC is stabilized to a commercial frequency reference. Then, the two lasers are locked to this HFLTC using the Pound–Drever–Hall (PDH) method which can narrow the linewidths and stabilize the frequencies of both lasers simultaneously. Finally, the transmitted lasers of HFLTC with each power up to about 100 μW, which act as seed lasers, are amplified using the injection locking method for single-atom Rydberg excitation. The linewidths of obtained lasers are narrowed to be less than 1 kHz, meanwhile the obtained lasers' phase noise around 750 kHz are suppressed about 30 dB. With the spectrally filtered lasers, we demonstrate a Rabi oscillation between the ground state and Rydberg state of single-atoms in an optical trap tweezer with a decay time of (67 ± 37) μs, which is almost not affected by laser phase noise. We found that the maximum short-term laser frequency fluctuation of a single excitation lasers is at ∼3.3 kHz and the maximum long-term laser frequency drift of a single laser is ∼46 kHz during one month. Our work develops a stable and repeatable method to provide multiple laser sources of ultra-low phase noise, narrow linewidth, and excellent frequency stability, which is essential for high precision atomic experiments, such as neutral atom quantum computing, quantum simulation, quantum metrology, and so on. [ABSTRACT FROM AUTHOR]

Published

2021

3. High-Fidelity Manipulation of the Quantized Motion of a Single Atom via Stern–Gerlach Splitting.

Author

Wang, Kun-Peng, Zhuang, Jun, He, Xiao-Dong, Guo, Rui-Jun, Sheng, Cheng, Xu, Peng, Liu, Min, Wang, Jin, and Zhan, Ming-Sheng

Subjects

RABI oscillations, ULTRACOLD molecules, OPTICAL tweezers, ATOMS, MAGNETIC fields, MICROWAVES

Abstract

We demonstrate high-fidelity manipulation of the quantized motion of a single 87Rb atom in an optical tweezer via microwave couplings induced by Stern–Gerlach splitting. The Stern–Gerlach splitting is mediated by polarization gradient of a strongly focused tweezer beam that functions as fictitious magnetic field gradient. The spatial splitting removes the orthogonality of the atomic spatial wavefunctions, thus enables the microwave couplings between the motional states. We obtain coherent Rabi oscillations for up to third-order sideband transitions, in which a high fidelity of larger than 0.99 is obtained for the spin-flip transition on the first order sideband after subtraction of the state preparation and detection error. The Stern–Gerlach splitting is measured at a precision of better than 0.05 nm. This work paves the way for quantum engineering of motional states of single atoms, and may have wide applications in few body physics and ultracold chemistry. [ABSTRACT FROM AUTHOR]

Published

2020