Refined Molecular Parameters for the Carbon Monoxide Stretching Band of the CO–CO2van der Waals Complex

## NOTE Refined Molecular Parameters for the CO-OCS van der Waals Complex in the OCS O-C Stretching Band In the only previous study of the CO -OCS van der Waals complex, is easily accomplished with SPFIT ) . The fit also included the 22 MWFT pure rotational transitions of ( 1 ) , which were given

The weakly bound van der Waals complex CO-N 2 O has been studied for the first time. Absorption spectra in the CO stretching region near 2150 cm 01 were recorded using a tunable diode laser spectrometer to probe the continuous supersonic jet from a slit-shaped nozzle. A total of 186 lines were measu

With the Cologne submillimeter-wave supersonic jet spectrometer, we extended molecular jet spectroscopy with backward wave oscillators up to frequencies of about 600 GHz. For the first time, the van der Waals stretching vibration of the Ar-CO molecular complex was detected in direct absorption. We m

Radiofrequency transitions within K = 2 asymmetry doublets have been observed for the CO2-CO van der Waals complex. A Stark effect measurement on the J = 2, K = 2 transition provides an electric dipole moment of µ = 0.2493(1) D. Combining this result with the permanent moment of CO, µCO = 0.1098 D,

The microwave rotational spectrum of the van der Waals trimer \(\mathrm{Ar}_{2}-\mathrm{CO}_{2}\) has been observed between 7 and \(18 \mathrm{GHz}\) using a Balle-Flygare type pulsed molecular beam microwave Fourier transform (MWFT) spectrometer. Twenty-one transitions, all \(b\)-type, \(K_{a}+K_{c

The high resolution IR spectra of HCCCN-CO 2 and HCCCN-N 2 have been studied using molecular beam optothermal spectroscopy. For both complexes, structural information has been obtained; HCCCN-CO 2 has been determined to be T-shaped with the CO 2 molecule at the N end of HCCCN, while N 2 -HCCCN was f