Rotational spectrum in the v6=1 and v3=1 levels of chloroform

The infrared spectrum of the lowest fundamental band \(\nu_{3}\) of \({ }^{13} \mathrm{CH}_{3} \mathrm{I}\) has been studied in the region \(470-550 \mathrm{~cm}^{-1}\) at a resolution of \(0.0027 \mathrm{~cm}^{-1}\). In this parallel band more than 1500 transitions have been assigned for subbands \

A representation of the effective rotational Hamiltonian in the form of optimum versions of a rational series of the perturbation theory is suggested for nonisolated molecular states. This representation is used to analyze the most complete set of precise transition frequencies in the rotational spe

Rotational and fine structure transitions have been observed between low rotational levels in the \(v=0-3\) levels of the \(\mathrm{OH} X^{2} \Pi\) state by tunable far-infrared spectroscopy. The rotational and fine structure constants of the ground state have been refined by least-squares fitting t

The two lowest vibrational states of 35 Cl 35 ClO 2 , v 4 = 1 (A ) and v 6 = 1 (A ), were investigated between 223 and 500 GHz. More than 250 rotational transitions were recorded with J and K a up to 71 and 34, respectively. The spectra are heavily perturbed by strong c-type and weaker a-type Coriol

The infrared spectrum in the range 400 -1600 cm Ϫ1 of isotopically pure H 3 Si 37 Cl has been recorded at high resolution (2.4 -6.6 ϫ 10 Ϫ3 cm Ϫ1 ) and analyzed. Fifteen bands have been studied, namely the four fundamentals 3 (543.968 cm Ϫ1 ), 6 (663.738 cm Ϫ1 ), 2 (947.982 cm Ϫ1 ), and 5 (950.657 c