A quantum-chemical study of BCN

The energetically possible ways of water condensation at the molecular level were considered. The quantum chemical calculations of the relative stability of elementary modules of the fractal structure without external fields using AM^, C N D ~/ ~, and MNW methods were done. It was shown that C N D 0

The hybridization effect on two important quantities, chemical hardness and chemical potential, has been studied by HF-SCF theory using a 6-31G basis set. The maximum hardness principle has been tested for C-C and C-H symmetric stretching with positive and negative mean amplitudes of vibration. For

Semiempirical and ab initio SCF calculations are reported for the Cs, fidkenms with isolated pentagons. The optimized geometries and relative stabilities are discussed. All methods applied predict two nearly isoenergetic structures with Ds and DZd symmetry to be the most stable of the 24 isomers con

Semi-empirical and ab initio calculations are reported for the five Crs fullerenes with isolated pentagons. The optimized geometries and relative stabilities are discussed. The D3s structure previously favored on the basis of simple Hilckel arguments is found to be the least stable isomer at all the