ACCURATE DETERMINATION OF ROTATIONAL ENERGY LEVELS IN THE GROUND STATE OF $^{12}$CH$_4$
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Date
2013
Authors
Abe, M.
Iwakuni, K.
Okubo, S.
Sasada, H.
Journal Title
Journal ISSN
Volume Title
Publisher
Ohio State University
Abstract
We have measured absolute frequencies of saturated absorption of 183 allowed and 21 forbidden transitions in the \nub{3} band of $^{12}$CH$_4$ using an optical comb-referenced difference-frequency-generation spectrometer from 86.8 to 93.1 THz (from 2890 to 3100 \wn) $^,$ . The pump and signal sources are a 1.06-$\mu $m Nd:YAG laser and a 1.5-$\mu $m extended-cavity laser diode. An enhanced-cavity absorption cell increases the optical electric field and enhances the sensitivity. The typical uncertainty is 3 kHz for the allowed transitions and 12 kHz for the forbidden transitions. Twenty combination differences are precisely determined, and the scalar rotational and centrifugal distortion constants of the ground state are thereby yielded as \vspace{1em} \\begin{tabular}{r@{ = }l@{ }r@{ = }l} $B_{\rm{s}}$ & (157 122 614.2 $\pm $ 1.5) kHz, & $D_{\rm{s}}$ & (3 328.545 $\pm $ 0.031) kHz, \\ $H_{\rm{s}}$ & (190.90 $\pm $ 0.26) Hz, and& $L_{\rm{s}}$ & ($-$13.16 $\pm $ 0.76) mHz. \\end{tabular} \vspace{1em} Here, $B_{\rm{s}}$ is the rotational constant and $D_{\rm{s}}$, $H_{\rm{s}}$ and $L_{\rm{s}}$ are the scalar quartic, sextic, octic distortion constants. The relative uncertainties are considerably smaller than those obtained from global analysis of Fourier-transform infrared spectroscopy.
Description
Author Institution: Department of Physics, Faculty of Science and Technology, Keio University, Yokohama, Japan