High-resolution investigation of the weak ν1+3ν21-ν21+ν3 band of CO2 around 2

Using high-resolution Fourier transform spectra of monoisotopic \(\mathrm{H}_{2}{ }^{80} \mathrm{Se}\) recorded in the 1.8 and \(1.55-\mu \mathrm{m}\) regions. an extensive analysis of the \(2 \nu_{1}+\nu_{2}, \nu_{1}+\nu_{2}+\nu_{3}, 3 \nu_{1}, 2 \nu_{1}+\nu_{3}\), and \(\nu_{1}+\) \(2 v_{3}\) band

High-resolution Fourier transform spectra of monoisotopic \(\mathrm{H}_{2}{ }^{\text {k0 }}\) Se have been recorded with a resolution of \(7 \times 10^{-3} \mathrm{~cm}^{-1}\) in the \(4210-4850 \mathrm{~cm}^{-1}\) spectral range. Their rovibrational analysis ![](nexus-images/b2208c9d82968a0fea9531

High-resolution Fourier transform spectra of a natural sample of hydrogen telluride and of monoisotopic H 2 130 Te have been recorded in the 3.2-4-0 mm spectral region where the 3n 2 , n 1 / n 2 , and n 2 / n 3 bands of this molecule absorb. The (030) rotational levels were least-squares fitted usin

The infrared spectra of 16 O 3 have been recorded in the 3700 cm 01 region, with a Fourier transform spectrometer at 0.008 cm 01 resolution. A White-type cell, ᐉ Å 32.16 m, filled with 42.8 Torr O 3 was used. This spectral region corresponds to the n 2 / 3n 3 and n 1 / n 2 / 2n 3 bands. The n 2 / 3n