Redox Isomerism in the S₃ State of the Oxygen‐Evolving Complex Resolved by Coupled Cluster Theory

Abstract: The electronic and geometric structures of the water-oxidizing complex of photosystem II in the steps of the catalytic cycle that precede dioxygen evolution remain hotly debated. Recent structural and spectroscopic investigations support contradictory redox formulations for the active-site Mn 4 CaO x cofactor in the final metastable S 3 state. These range from the widely accepted Mn IV 4 oxo-hydroxo model, which presumes that OÀ O bond formation occurs in the ultimate transient intermediate (S 4 ) of the catal… Show more

“…Nevertheless, a very recent theoretical study considers a peroxidic intermediate in the S 3 state as unlikely. 96 By contrast, our substrate water exchange data are inconsistent with nucleophilic attack mechanisms between W3 and W2, 51,97–99 and geminal coupling between W2 and O5 at Mn4 (ref. 30, 100 ) (for details see ESI Text 4 and Fig.…”

The exchange of the fast substrate water in the S₂ state of photosystem II is limited by diffusion of bulk water through channels – implications for the water oxidation mechanism

“…Nevertheless, a very recent theoretical study considers a peroxidic intermediate in the S 3 state as unlikely. 96 By contrast, our substrate water exchange data are inconsistent with nucleophilic attack mechanisms between W3 and W2, 51,97–99 and geminal coupling between W2 and O5 at Mn4 (ref. 30, 100 ) (for details see ESI Text 4 and Fig.…”

The exchange of the fast substrate water in the S₂ state of photosystem II is limited by diffusion of bulk water through channels – implications for the water oxidation mechanism

“…Thus, different extrapolations of local parameters have been proposed. For example, one can extrapolate to the complete PNO space using the equation E ∞ = E x + F ⋅ ( E y − E x ), where E x and E y are the correlation energies calculated with T CutPNO =10 − x and 10 − y , E ∞ is the extrapolated correlation energy at the PNO space limit, and F is a constant with the recommended value of 1.5 [68–70] …”

“…[225] Drouso and Pantazis used DLPNO-CCSD(T) to calculate the relative energy of two isomers of S 3 : the S = 6 Mn IV 4 oxo-hydroxo model and the S = 7 Mn III 2 Mn IV 2 peroxo model. [70] Yamaguchi et al introduced a series of studies on Mn 4 CaO 5 with DLPNO-CCSD(T): ten S 0 structures, [226] twelve S = 7 S 1 structures, [227] and various S 2 structures with S = 13/2, 5/2, 1/ 2. [228,229] The energy spectrum of [4FeÀ 4S] was first explored with DMRG by Sharma et al, [230] followed by two appers of Li Manni et al using FCIQMC.…”

Ab Initio Methods in First‐Row Transition Metal Chemistry

“…For example, CPS(6/7) extrapolation yields errors in relative energies that are typically less than 0.3 kcal/mol in comparison to canonical CCSD(T) for the most challenging reactions of the GMTKN55 superset, 20 as shown in ref ( 45 ), as well as on many other molecular systems. 46 − 48 In particular, the accurate quantification of NCI energies 20 , 49 − 64 is a very hot topic of research. On the most popular benchmark set of NCIs (S66), 65 − 67 CPS(6/7) provides a mean absolute error (MAE) of only 0.03 kcal/mol at the complete basis set (CBS) limit relative to the SILVER 61 reference values.…”

Addressing the System-Size Dependence of the Local Approximation Error in Coupled-Cluster Calculations