Open-shell molecules in doubly degenerate (2)E electronic states are subject to the E ⊗ e Jahn-Teller effect and spin-orbit interactions. The rotational structure of the ground vibrational level of the X(+) (2)E ground state of CH(3)F(+) has been observed by high-resolution photoelectron spectroscopy. In contrast to what is observed in other members of the isoelectronic families CH(3)X(+) (X=Cl, Br, I) and CH(3)Y (Y=O, S), the spin-orbit interaction does not lead to a splitting of the ground state of CH(3)F(+). Observed trends in the spectra of the X (2)E ground states of these molecules are summarized. Whereas certain trends, such as the reduction of the observable effects of the Jahn-Teller interactions and the increase of the spin-orbit splitting with increasing nuclear charge of X and Y are easily understood, other trends are more difficult to explain, such as the much reduced spin-orbit splitting in CH(3)F(+) compared to CH(3)O. A simple two-state excitonic model is used to account for the trends observed within the series of the methyl-halide radical cations and also the similarities and differences between CH(3)F(+) and the isoelectronic CH(3)O radical. Within this model, the electron hole in the (2)E ground states of CH(3)X(+) and CH(3)Y is described in terms of contributions from the halogenic (or chalcogenic) p(x, y) orbitals and the pyramidal-methylic (e) orbitals. This model enables a global, semi-quantitative description of the combined effects of the Jahn-Teller and spin-orbit interactions in these molecules and also a simple interpretation of the spin-orbit-coupling reduction factor ζ(e).