New Journal of Physics (Jan 2020)

Multispectrum rotational states distribution thermometry: application to the 3ν1 + ν3 band of carbon dioxide

  • R Gotti,
  • M Lamperti,
  • D Gatti,
  • S Wójtewicz,
  • T Puppe,
  • Y Mayzlin,
  • B Alsaif,
  • J Robinson-Tait,
  • F Rohde,
  • R Wilk,
  • P Leisching,
  • W G Kaenders,
  • P Laporta,
  • M Marangoni

DOI
https://doi.org/10.1088/1367-2630/aba85d
Journal volume & issue
Vol. 22, no. 8
p. 083071

Abstract

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In this paper we propose multispectrum rotational states distribution thermometry as an optical method for primary thermometry. It relies on a global fitting of multiple absorption lines of the same band at different pressures. The approach allows leveraging both the temperature-dependent Doppler width and the temperature-dependent distribution of line intensities across the ro-vibrational band. We provide a proof-of-principle demonstration of the approach on the 3 ν _1 + ν _3 band of CO _2 , for which several accurate line-strength models of both theoretical and experimental origin are available for the global fitting. Our experimental conditions do not allow to test the methodology beyond a combined uncertainty of 530 ppm, but the comparative analysis between different line-strength models shows promise to reduce the error budget to few tens of ppm. As compared to Doppler-broadening thermometry, the approach is advantageous to mitigate systematic errors induced by a wrong modelling of absorption line-shapes and to reduce, for a given experimental dataset, the statistical uncertainty by a factor of 2. When applied in a reverse way, i.e. using a gas of known temperature, the approach becomes a stringent testbed for the accuracy of the adopted line-strength model.

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