Related papers: Extending the coherence time limit of a single-alkali-atom qubit by suppressing phonon-jumping-induced decoherence

Extending the coherence time limit of a single-alkali-atom qubit by suppressing phonon-jumping-induced decoherence

URL: http://arxiv.org/abs/2312.11196v3
Date: Thu, 27 Feb 2025 04:03:12 GMT
Title: Extending the coherence time limit of a single-alkali-atom qubit by suppressing phonon-jumping-induced decoherence
Authors: Zhuangzhuang Tian, Haobo Chang, Xin Lv, Mengna Yang, Zhihui Wang, Pengfei Yang, Pengfei Zhang, Gang Li, Tiancai Zhang,
Abstract summary: Coherence time of qubit encoded in electronic states is one of the most important parameters.<n>Coherence time is assumed to be determined by relative stability of the energy between the electronic states.<n>We propose a complete description of the decoherence of a qubit encoded in two ground electronic states of an optically trapped alkali atom.
Score: 22.585565798915038
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In the fields of quantum metrology and quantum information processing with the system of optically trapped single neutral atoms, the coherence time of qubit encoded in the electronic states is regarded as one of the most important parameters. Longer coherence time is always pursued for higher precision of measurement and quantum manipulation. The coherence time is usually assumed to be merely determined by relative stability of the energy between the electronic states, and the analysis of the decoherence was conducted by treating the atom motion classically. We proposed a complete description of the decoherence of a qubit encoded in two ground electronic states of an optically trapped alkali atom by adopting a full description of the atomic wavefunction. The motional state, i.e., the phonon state, is taken into account. In addition to decoherence due to the variance of differential light shift (DLS), a new decoherence mechanism, phonon-jumping-induced decoherence (PJID), was discovered and verified experimentally. The coherence time of a single-cesium-atom qubit can be extended to $T_2\approx 20$ s by suppressing both the variances of DLS and PJID by trapping the atom in a blue-detuned bottle beam trap (BBT) and preparing the atom in its three-dimensional motional ground states. The coherence time is the longest for a qubit encoded in an optically trapped single alkali atom. Our work provides a deep understanding of the decoherence mechanism for single atom qubits and thus provides a new way to extend the coherence time limit. The method can be applied for other atoms and molecules, opening up new prospects for high-precision control the quantum states of optically trapped atoms or molecules.

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