Resonance Raman (RR) and FTIR spectra were observed for 1,4-benzoquinone (BQ) and its 18 O 2 and d 4 isotopomers in their reduced states and their protonated forms, including the anion radical (BQ •-), semiquinone radical (BQH • ), dianion (BQ 2-), and protonated anion (BQH -) in water and acetonitrile. The reduced species were generated electrochemically, and the RR spectra were excited in situ at 441.6, 363.8, 351.1, 325, and 235 nm in resonance with the three lowest electronic transitions. The observed bands were assigned empirically on the basis of the observed 18 O 2 -and d 4 -isotopic frequency shifts and depolarization ratios and further with ab initio MO calculations at the MP2 level. In contrast with neutral BQ, the 18 O atoms of BQ •-and BQ 2were rapidly exchanged with bulk water during the RR measurements for aqueous solutions. Upon reduction from BQ to BQ •-and BQ 2-, the CdO stretching mode (ν 7a in Wilson's notation) shifts from 1639 to 1452 and 1275 cm -1 , respectively, while the ν 8a mode exhibits smaller shifts from 1666 to 1609 and 1596 cm -1 , respectively. The ν 8a and ν 8b separation was 293, 149, and 81 cm -1 for BQ, BQ •-, and BQ 2-, respectively, indicating that the six-membered ring increasingly approaches a benzenoid ring as reduction proceeds. These frequency changes are in qualitative agreement with those expected from the optimized bond lengths of the MO calculations. The RR spectra of BQHwere close to that of BQ 2-, suggesting that the extra charges of BQ 2are mainly localized on the two oxygen atoms. Three b 3g vibrations were resonance enhanced for BQ •-via vibronic coupling, and this determines the symmetry of the first allowed electronic excited state to be 2 B 3u in the D 2h group. Assuming D 2h symmetry for BQ •-predicts the presence of five polarized RR bands in the region below 1700 cm -1 , but nine fundamentals were observed in addition to several overtones and combinations. In addition, one band appears both in the IR and the RR spectra. Therefore, practical molecular symmetry is reduced to C s owing to solvation.