2017
DOI: 10.1021/jacs.7b07634
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Photosystem II Acts as a Spin-Controlled Electron Gate during Oxygen Formation and Evolution

Abstract: The oxygen evolution complex (OEC) of photosystem II (PSII) is intrinsically more active than any synthetic alternative for the oxygen evolution reaction (OER). A crucial question to solve for the progress of artificial photosynthesis is to understand the influential interactions during water oxidation in PSII. We study the principles of interatomic electron transfer steps in OER, with emphasis on exchange interactions, revealing the influence of delocalizing ferromagnetic spin potentials during the catalytic … Show more

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Cited by 63 publications
(65 citation statements)
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“…When the single electrons in different •OH species are in different spin directions, the hydroxyl radical will combine easily to generate H 2 O 2 17,22 , which will reduce the effective proportion of •OHs to take part in the surface oxidation reaction. On the contrary, •OHs with single electrons in the same spin direction are not easy to combine 17,23,46 , thus promoting the surface reactions of water splitting and degradation (especially for the case of TiO 2 -10).…”
Section: Resultsmentioning
confidence: 99%
“…When the single electrons in different •OH species are in different spin directions, the hydroxyl radical will combine easily to generate H 2 O 2 17,22 , which will reduce the effective proportion of •OHs to take part in the surface oxidation reaction. On the contrary, •OHs with single electrons in the same spin direction are not easy to combine 17,23,46 , thus promoting the surface reactions of water splitting and degradation (especially for the case of TiO 2 -10).…”
Section: Resultsmentioning
confidence: 99%
“…In this regard, one of the fingerprints in spintro‐catalysis is the general reduction of the free activation energies by a quantity that is proportional to the FM spin‐moment of the active sites. Within this correlation, we have used the Heisenberg Hamiltonian to quantify the QEI; that is: H QEI =▵J QEI ⋅ S cat where, ▵J QEI is a catalytic exchange coupling constant and S cat is the average spin moment at the active sites …”
Section: Methodsmentioning
confidence: 99%
“…Within this correlation, we have used the Heisenberg Hamiltonian to quantify the QEI; that is: H QEI =~J QEI ·S cat where,~J QEI is a catalytic exchange coupling constant and S cat is the average spin moment at the active sites. [31] We start the analysis from nitrogen defective unit cells, as the active catalysts present nitrogen vacancies at reaction conditions. [25] For that, we subtracted one of the sixteen nitrogen atoms in the unit cell of Fe 3 Mo 3 N, Co 3 Mo 3 N and FeCo 2 Mo 3 N, [32] as well as in an equivalent (with respect to the number of nitrogen atoms) Ni 2 Mo 3 N supercell (2 2 1); [33] thus making stoichiometries of the form M x Mo 3 N 0.94 .…”
Section: On the Role Of Ferromagnetic Interactions In Highly Active Mmentioning
confidence: 99%
“…21,22 Nature has evolved excellent magnetic catalysts from abundant 3d-metals, e.g. during photosynthesis 23 , via engineering QSEI.…”
Section: Introductionmentioning
confidence: 99%