IR-Spectroscopic Characterization of Acetophenone Complexes with Fe+, Co+, and Ni+ Using Free-Electron-Laser IRMPD

Abstract

The gas-phase complexes M(+)(acet)(2), where M is Fe, Co, or Ni and acet is acetophenone, were studied spectroscopically by infrared multiple-photon dissociation (IRMPD) supported by density functional (DFT) computations. The FELIX free electron laser was used to give tunable radiation from approximately 500 to 2200 cm(-1). The spectra were interpreted to determine the metal-ion binding sites on the ligands (oxygen (O) or ring (R)) and to see if rearrangement of the ligand(s) to toluene plus CO occurred. For Ni(+), O binding was found to predominate (similar to the previously studied Cr(+) case), with less than approximately 10% of R-bound ligands in the population. For Co(+), a roughly equal mixture of R-bound and O-bound ligands was present; based on the computed thermochemistry, the OR complex was considered likely to predominate. Fe(+) complexes appeared largely O-bound, but with clear evidence for some R-binding. The exceptionally large extent of R binding for Co(+) highlights the special affinity of this metal ion for aromatic ring ligands. In contrast, the predominant O binding for Ni(+) emphasizes the especially high metal-ion affinity of the O site of acetophenone compared with other ligands such as anisole where R binding of Ni(+) predominates. The spectra did not indicate significant intracomplex rearrangement of ligands to toluene plus CO, and in particular for the Co(+) case the absence of a metal-bound C triple bond O stretching peak near 2100 cm(-1) strongly ruled out such a rearrangement.