Symmetry, Vol. 18, Pages 974: Substitution Driven Local Symmetry Effect in Halogen–π Complexes of Alkenes and Alkynes: A Quantum Chemical Study Symmetry doi: 10.3390/sym18060974 Authors: Jelena M. Živković Sonja S. Zrilić Snežana D. Zarić Nebojša Đ. Pantelić Dušan S. Dimić This study presents a quantum chemical investigation of halogen–π interactions involving halogen molecules (F2, Cl2, Br2, and I2) and a series of π-systems, including benzene, alkenes, and alkynes. Special emphasis is placed on the role of the position of the unsaturated bond (terminal vs. internal) in determining the strength and nature of these interactions. Geometry optimizations and interaction energies were calculated at the wB97X-D3/def2-TZVPP level of theory, with additional validation against CCSD(T)/CBS data. Energy decomposition analysis using SAPT0 and QTAIM analysis were also performed. The results show a clear increase in interaction strength from F2 to I2, with interaction energies ranging from −0.47 to −5.61 kcal/mol. The position of the double or triple bond and the local symmetry of the π-system significantly influence interaction energies, with internal and more substituted alkenes and alkynes forming stronger interactions than terminal analogs. SAPT analysis shows that halogen–π interactions are governed by a balance of electrostatic and dispersion contributions, with electrostatics representing the largest attractive term in most cases, whereas dispersion becomes increasingly important for heavier halogens and more extended π-systems and benzene. QTAIM analysis confirms the noncovalent nature of these interactions, with increasing electron density at bond critical points correlating with stronger binding.
