Laser-Based Primary Thermometry: A Review

Gotti, Riccardo; Lamperti, Marco; Gatti, Davide; Marangoni, Marco

doi:10.1063/5.0055297

Cited by 6 publications

(5 citation statements)

References 107 publications

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“…It should be noted that the Voigt profile provides an excellent fit to experimentally measured spectra for a wide range of conditions; however, departures from the Voigt lineshape are known and have been studied, and are particularly relevant in the field of Doppler-broadened thermometry [126][127][128][129][130][131][132].…”

Section: Voigt Lineshapementioning

confidence: 99%

Laser spectroscopy of hot atomic vapours: from ’scope to theoretical fit

et al. 2022

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The spectroscopy of hot atomic vapours is a hot topic. Many of the work-horse techniques of contemporary atomic physics were first demonstrated in hot vapours. Alkali-metal atomic vapours are ideal media for quantum-optics experiments as they combine: a large resonant optical depth; long coherence times; and well-understood atom-atom interactions. These features aid with the simplicity of both the experimental set up and the theoretical framework. The topic attracts much attention as these systems are ideal for studying both fundamental physics and has numerous applications, especially in sensing electromagnetic fields and quantum technology. This tutorial reviews the necessary theory to understand the Doppler broadened absorption spectroscopy of alkali-metal atoms, and explains the data taking and processing necessary to compare theory and experiment. The aim is to provide a gentle introduction to novice scientists starting their studies of the spectroscopy of thermal vapours whilst also calling attention to the application of these ideas in the contemporary literature. In addition, the work of expert practitioners in the field is highlighted, explaining the relevance of three extensively-used software packages that complement the presentation herein.

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Section: Voigt Lineshapementioning

confidence: 99%

Laser spectroscopy of hot atomic vapours: from ’scope to theoretical fit

et al. 2022

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“…The new definition of the kelvin is based upon the Boltzmann constant, k B = 1.380649 × 10 −23 JK −1 -a factor that converts thermodynamic temperature to energy. In the route towards the re-definition, a whole host of national metrology institutes worked diligently to produce the most accurate measurements of the Boltzmann constant (the Boltzmann project [45]), using AGT [7], JNT [8], dielectric constant gas thermometry (DCGT [46]) and Doppler broadening thermometry (DBT [47]), to name a few. Three of them-AGT, DCGT and JNT-were utilized for the final CODATA k B value [48].…”

Section: Emerging Technologies For Primary Thermometrymentioning

confidence: 99%

“…The principle of DBT is to record the Doppler profile of a molecular (or atomic) absorption line of a gas in thermodynamic equilibrium [47,65] (see figure 8). The absorption line shape of single rotational-vibrational (rovibrational) molecular line is dominated at very low pressure by Doppler broadening and is a simple Gaussian profile, which reflects the Maxwell-Boltzmann velocity distribution of gas particles along the laser beam axis.…”

Section: Doppler-line Broadening Thermometrymentioning

confidence: 99%

Emerging technologies in the field of thermometry

Dedyulin

Ahmed²,

Machin³

2022

Meas. Sci. Technol.

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The past decade saw the emergence of new temperature sensors that have the potential to disrupt a century-old measurement infrastructure based on resistance thermometry. In this review we present an overview of emerging technologies that are either in the earliest stages of metrological assessment or in the earliest stages of commercial development and thus merit further consideration by the measurement community. The following emerging technologies are reviewed: Johnson noise thermometry, optical refractive-index gas thermometry, Doppler line broadening thermometry, optomechanical thermometry, ﬁber-coupled phosphor thermometry, ﬁber-optic thermometry based on Rayleigh, Brillouin and Raman scattering, ﬁber-Bragg-grating thermometry, Bragg-waveguide-grating thermometry, ring-resonator thermometry, and photonic-crystal-cavity thermometry. For each emerging technology, we explain the working principle, highlight the best known performance, list advantages and drawbacks of the new temperature sensor and present possibilities for future developments.

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“…Such an approach will be needed to make autonomous production truly a reality. Such approaches could be through practical Johnson Noise Thermometry (where practical demonstrator devices already exist) [69,70] and in the longer-term small-scale Doppler Broadening Thermometry [71,72] as well as other photonic based approaches [73].…”

Section: Future Temperature Realisation and Disseminationmentioning

confidence: 99%