Application of cavity ring-down spectroscopy to the Boltzmann constant determination

Y. R. Sun; H. Pan; C.-F. Cheng; A.-W. Liu; J.-T. Zhang; S.-M. Hu

doi:10.1364/OE.19.019993

Optics Express
Vol. 19,
Issue 21,
pp. 19993-20002
(2011)
•https://doi.org/10.1364/OE.19.019993

Application of cavity ring-down spectroscopy to the Boltzmann constant determination

Y. R. Sun, H. Pan, C.-F. Cheng, A.-W. Liu, J.-T. Zhang, and S.-M. Hu

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Y. R. Sun, H. Pan, C.-F. Cheng, A.-W. Liu, J.-T. Zhang, and S.-M. Hu, "Application of cavity ring-down spectroscopy to the Boltzmann constant determination," Opt. Express 19, 19993-20002 (2011)

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Abstract

The Boltzmann constant can be optically determined by measuring the Doppler width of an absorption line of molecules at gas phase. We propose to apply a near infrared cavity ring-down (CRD) spectrometer for this purpose. The superior sensitivity of CRD spectroscopy and the good performance of the near-ir lasers can provide ppm (part-per-million) accuracy which will be competitive to present most accurate result obtained from the speed of sound in argon measurement. The possible influence to the uncertainty of the determined Doppler width from different causes are investigated, which includes the signal-to-noise level, laser frequency stability, detecting nonlinearity, and pressure broadening effect. The analysis shows that the CRD spectroscopy has some remarkable advantages over the direct absorption method proposed before. The design of the experimental setup is presented and the measurement of C₂H₂ line near 0.8 μm at room temperature has been carried out as a test of the instrument.

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Fig. 1 Relative deviations in γ_D resulting from the noise level and frequency uncertainty.

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Fig. 2 Relative deviation on the Doppler line width from spectrum recorded with different sample pressure. The linear fit gives the extrapolation to the zero pressure limit.

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Fig. 3 Relative deviations in the determined line width with different nonlinearity coefficients in the detection, for direct absorption measurement (upper) and for cavity ring-down measurement (lower).

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Fig. 4 Schematics of a frequency-stabilized CRDS setup. AOM: acousto-optic modulator; EOM: electro-optic modulator. DAQ: Data acquisition card.

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Fig. 5 Spectrum of a ¹²C₂H₂ line near 788 nm at the room temperature. Left panel: observed and simulated spectrum (upper) and the fitting residual (lower). Right panel: temperature values derived from the Gaussian widths of a series of spectrum obtained with different sample gas pressure.

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Equations (4)

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\frac{γ_{D}}{ν_{0}} = {(\frac{8 k_{B} T ln 2}{{m c}^{2}})}^{1 / 2}

τ = \frac{L / c}{- ln R + α L}

α = \frac{1}{c τ} + \frac{ln R}{L}

I^{'} = I_{0} + δ I_{0}^{2}

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