Abstract

The CH4+ ion is known to be involved in many ion–molecule reactions, presumably including those leading to the precursors of life, but little experimental information about it is available. In the present investigation, the energy of CH4+ in various geometries is calculated by the restricted SCF MO method using a Gaussian basis set. The ion is distorted from the regular tetrahedron because of the Jahn–Teller effect. Two stable geometries are found: tetragonal (D2d), RCH = 2.0943 bohr, dihedral angle = 53.3°, E = −39.74593 hartree; trigonal (C3υ), RCH1 = 2.5859, RCH2,3,4 = 2.0121, H1CH2 angle = 98.28°, E = − 39.74156 hartree. Other geometries investigated are, in order of decreasing energy, regular tetrahedron, square plane, and CH3+ + H. The relations among these geometries are discussed in terms of orbital energies, energy components, and population analysis.