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Data for "Quantum state tracking and control of a single molecular ion in a thermal environment''

Data provided by  National Institute of Standards and Technology

Supplementary data for the article "Quantum state tracking and control of a single molecular ion in a thermal environment" by Yu Liu, Julian Schmidt, Zhimin Liu, David R. Leibrandt, Dietrich Leibfried, Chin-wen Chou, submitted to Science in 2024. The manuscript describes a quantum state-specific investigation of the molecular state evolution of a single CaH+ ion in a thermal environment. The molecular state can be tracked in real time with single quantum-state resolution and the thermal radiation-induced transitions can be reversed with coherent molecular state manipulation according to the outcomes of state measurements. Results on the transition rates are used to infer the properties of the thermal environment. The data may be used to reproduce the plots shown in the figures.

About this Dataset

Updated: 2025-04-06
Metadata Last Updated: 2024-06-27 00:00:00
Date Created: N/A
Data Provided by:
Dataset Owner: N/A

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Title Data for "Quantum state tracking and control of a single molecular ion in a thermal environment''
Description Supplementary data for the article "Quantum state tracking and control of a single molecular ion in a thermal environment" by Yu Liu, Julian Schmidt, Zhimin Liu, David R. Leibrandt, Dietrich Leibfried, Chin-wen Chou, submitted to Science in 2024. The manuscript describes a quantum state-specific investigation of the molecular state evolution of a single CaH+ ion in a thermal environment. The molecular state can be tracked in real time with single quantum-state resolution and the thermal radiation-induced transitions can be reversed with coherent molecular state manipulation according to the outcomes of state measurements. Results on the transition rates are used to infer the properties of the thermal environment. The data may be used to reproduce the plots shown in the figures.
Modified 2024-06-27 00:00:00
Publisher Name National Institute of Standards and Technology
Contact mailto:[email protected]
Keywords Molecular quantum state control , molecular physics , quantum information , chemical physics 
{
    "identifier": "ark:\/88434\/mds2-3389",
    "accessLevel": "public",
    "contactPoint": {
        "hasEmail": "mailto:[email protected]",
        "fn": "Chin-wen Chou"
    },
    "programCode": [
        "006:045"
    ],
    "landingPage": "https:\/\/data.nist.gov\/od\/id\/mds2-3389",
    "title": "Data for \"Quantum state tracking and control of a single molecular ion in a thermal environment''",
    "description": "Supplementary data for the article \"Quantum state tracking and control of a single molecular ion in a thermal environment\" by Yu Liu, Julian Schmidt, Zhimin Liu, David R. Leibrandt, Dietrich Leibfried, Chin-wen Chou, submitted to Science in 2024. The manuscript describes a quantum state-specific investigation of the molecular state evolution of a single CaH+ ion in a thermal environment. The molecular state can be tracked in real time with single quantum-state resolution and the thermal radiation-induced transitions can be reversed with coherent molecular state manipulation according to the outcomes of state measurements. Results on the transition rates are used to infer the properties of the thermal environment. The data may be used to reproduce the plots shown in the figures.",
    "language": [
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    "distribution": [
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/appearance_time_histogram_J_0_to_J1.csv",
            "description": "(For Figure 2A) number of J = 0 to J = 1 transitions sorted into bins of the time after an initial preparation of the CaH+ in the J = 0 minus sublevel.",
            "mediaType": "text\/csv",
            "title": "Figure 2A"
        },
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/entry_and_exit_times_J_1.csv",
            "description": "(For Figure 1C) The times at which the CaH+ molecule enter and exit the J = 2 manifold.",
            "mediaType": "text\/csv",
            "title": "Figure 1C"
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        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/entry_and_exit_times_J_2.csv",
            "description": "(For Figure 1C) The times at which the CaH+ molecule enter and exit the J = 2 manifold.",
            "mediaType": "text\/csv",
            "title": "Figure 1C"
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        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/histogram_of_recoveries_from_J_0_and_J_2.csv",
            "description": "(For Figure 3B) A tally of the number of recoveries from J = 0 and J = 2 during the state tracking experiment.",
            "mediaType": "text\/csv",
            "title": "Figure 3B"
        },
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/pressure_dependence_of_J_0_to_J_1_transitions.csv",
            "description": "(For Figure 2C) dependence of the J = 0 to J = 1 transition rate on the Ca+-CaH+ ion crystal reorder rate; dependence of the vacuum pressure on the Ca+-CaH+ ion crystal reorder rate.",
            "mediaType": "text\/csv",
            "title": "Figure 2C"
        },
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/real_time_state_tracking_data.csv",
            "description": "(For Figure 3C) times at which CaH+ transitions to J = 0 or J = 2 manifolds.",
            "mediaType": "text\/csv",
            "title": "Figure 3C"
        },
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/sublevel_distribution_J0_to_J1.csv",
            "description": "(For Figure 2B) number of transitions to various sublevels of J = 1 when the CaH+ is prepared in either J = 0 minus or plus sublevels.",
            "mediaType": "text\/csv",
            "title": "Figure 2B"
        },
        {
            "downloadURL": "https:\/\/data.nist.gov\/od\/ds\/mds2-3389\/tracking_time_series.csv",
            "description": "(For Figure 3D) times at which CaH+ enters and exits J = 1 during the tracking experiment.",
            "mediaType": "text\/csv",
            "title": "Figure 3D"
        },
        {
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        "name": "National Institute of Standards and Technology"
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    "theme": [
        "Physics:Quantum information science",
        "Physics:Atomic, molecular, and quantum"
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    "keyword": [
        "Molecular quantum state control",
        "molecular physics",
        "quantum information",
        "chemical physics"
    ]
}