The far-infrared spectrum of fluoroform (CHF3)

The milimeter-wave, submillimeter-wave, and FIR spectra of the ground state of \(\mathrm{CHF}_{3}\) have been observed and analyzed up to \(J=78\). The resulting spectroscopic constants are: \(B_{0} / \mathrm{MHz}=\) \(10348.8706(2), D_{j} / \mathrm{kHz}=11.34482(13), D_{J K} / \mathrm{kHz}=-18.1176

We have measured the rotational spectrum of \(\mathrm{H}^{127} \mathrm{I}\) from 0.38 to \(4.58 \mathrm{THz}\left(13-153 \mathrm{~cm}^{-1}\right)\), encompassing the \(R(0)\) through \(R(11)\) rotational lines. using the \(\mathrm{CO}_{2}\) laser difference method for generating coherent far-infrare

The ground state rotational spectrum of \(\mathrm{CHF}_{2} \mathrm{Cl}\) has been observed and analyzed in the frequency region \(70-1280 \mathrm{GHz}\). Transitions with values of \(J\) up to 80 have been observed and the centrifugal distortion analysis of the spectrum has been performed using both

The absorption spectrum of SiHq from 32 to 400 cm -' has revealed two soparatc bar.ds, one linear in density and one quadratic. From the linex band, the electric dipole moment produced in the ground vibronic state by centrifugal distortion effects has been estimated to be 9.3 X lob6 D in magnitude.

We have measured the frequencies of 17 transitions in the far-infrared spectrum of the hydroperoxyl radical, \(\mathrm{HO}_{2}\), from 2.5 to \(5.9 \mathrm{THz}\), encompassing rotational levels up to \(N=19\) and \(K_{-1}\) \(=5\). These measured transition frequencies are combined with previously