The structure and vibrational frequencies of the ArH3+ ion and its isotopomers

The geometry of NHzNO has been optimised at the HF level of theory with basis sets ranging from STO-3G to 6-3 I 1 G\*\*. The lowest-energy structure is not planar as previously predicted. The geometry of NHzNO was optimised at the MP2/6-3 lG\*\* level of theory. The geometry of the planar structure

Large basis, well-correlated ab initio wlculations have been carried out to predict the J = 1 -0 rotariondl transition frequency and the helium 5trctching frequency of the species HeHCNH\* and HeHNCH+. These unobserved ions are suzcsted as being important in interstellar ion-molecule reactions. and

The ArHN~ ion has been studied using correlated ab initio methods. Geometric structures, vibration frequencies and intensities have been computed using the MP2 method and large basis sets. The cluster is linear with the structure ArHNN and Ar-H distance of 1.835 A. The complex is bound by approximat

Several structures of C24 have been studied using different density functional methods. Using the B3LYP (Becke 3parameter Lee-Yang-Parr) method, fingerprint-quality infrared spectra have been computed for all species. The computed geometries differ substantially from those obtained at the SCF level