Author(s)

Masashi Katsuda, Masaki Mitani, Yasunori Yoshioka

Chemistry Department for Materials, Graduate School of Engineering, Mie University, Tsu, Japan.

Electronic and molecular structures of [(X)_mMn(μ-oxo)₂Mn(Y)_n]^q+ (X, Y = H₂O, OH and O), which are Mn cluster models at catalytic sites of OEC, were studied by broken-symmetry unrestricted B3LYP method. Two paths from the S₀ to S₃ states of Kok cycle were investigated. One is a path starting from [Mn(II) (μ-oxo)₂Mn(III)] at the S₀ state, and another is from [Mn(III) (μ-oxo)₂Mn(III)] at the S₀. Results found in this study are summarized as, 1) In [Mn(II), Mn(III)], it is not possible that H₂O molecules coordinate to the Mn atoms with retaining the octahedral configuration. 2) The OHˉ anion selectively coordinates to Mn(IV) rather than Mn(III). 3) When the oxo atom directly bind to the Mn atom, the Mn atom must be a Mn(IV). From these results, the catalytic mechanism for four-electron oxidation of two H₂O molecules in OEC is proposed. 1) The Mn₄(II, III, IV, IV) at S₀ is ruled out. 2) For Mn₄(III, III, IV, IV) at S₁, the Mn atom coordinated by OHˉ anion is a Mn(IV) not Mn(III). 3) Only Mn(III) ion which is coordinated by a H₂O molecule at S₀ plays crucial roles for the oxidation.

Oxygen Evolving Complex; Manganese Binuclear; Oxidation Mechanism

Katsuda, M. , Mitani, M. and Yoshioka, Y. (2012) A B3LYP study on electronic structures of [(X)_mMn(μ-oxo)₂Mn(Y)_n]^q+ (X, Y = H₂O, OH and O) as a Mn cluster model of OEC. Journal of Biophysical Chemistry, 3, 111-126. doi: 10.4236/jbpc.2012.32013.