Numerical modeling for trapped-ion thermometry using dark resonances

• URL: http://arxiv.org/abs/2505.04459v2
• Date: Thu, 08 May 2025 19:19:12 GMT
• Title: Numerical modeling for trapped-ion thermometry using dark resonances
• Authors: Muriel Bonetto, Nicolás Adrián Nuñez Barreto, Christian Tomás Schmiegelow, Cecilia Cormick,
• Abstract summary: We discuss several techniques with simplified dynamical equations for the numerical simulation of the spectrum of a trapped ion undergoing thermal motion.<n>We observe that mimicking the effect of thermal motion by means of additional dephasing is computationally very convenient but can lead to significant errors in the estimation of the temperature.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: The accurate simulation of vibrational energy transport and quantum thermodynamics with trapped ions requires good methods for the estimation of temperatures. One valuable tool with this purpose is based on the fit of dark resonances in the fluorescence spectrum. However, the reliability of the procedure is still unclear. Here, we discuss several techniques with simplified dynamical equations for the numerical simulation of the spectrum of a trapped ion undergoing thermal motion, identifying advantages and limitations of each method. We start with a simplified three-level model to provide a better insight into the approximations involved and then move on to tackle the experimentally relevant case of an eight-level calcium ion. We observe that mimicking the effect of thermal motion by means of additional dephasing is computationally very convenient but can lead to significant errors in the estimation of the temperature. However, this can be counteracted by a proper calibration, supporting the use of dark resonances as a practical thermometer.

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