Abstract:
Complexes between para-substituted cationic phenol and SeH2 have been investigated in electronic ground state at the B3LYP, B3PW91, and ωB97xD levels of theory using 6-311++G(3df,3pd) basis set. Various electron-donating and withdrawing substituents (NH2, OH, CH3, H, F, Cl, CN, and NO2) are used to characterize electronic substituent effect on intermolecular +OH⋯Se hydrogen bond. Electron withdrawing substituent increases hydrogen bond stabilization energy and red shift in OH stretching frequency. Introduction of a positive charge transforms weak hydrogen bond of neutral OH⋯Se type into a strong hydrogen bond. Complexation induced changes on various hydrogen bond parameters, such as, stabilization energy, change in OH bond length, change in OH stretching frequency, extent of charge transfer from hydrogen bond acceptor to donor, hydrogen bond orders, electron density at the hydrogen bond critical point exhibit conventional electronic substitution effect. Stabilization energy of +OH⋯Y hydrogen bond are similar in the complexes between cationic phenol and SH2/SeH2, whereas it is almost twice with OH2 in case of +OH⋯Y hydrogen bond.