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arxiv 1810.10196 v2 pith:WJL3EHUS submitted 2018-10-24 physics.chem-ph cond-mat.str-elquant-ph

Electronic landscape of the P-cluster of nitrogenase as revealed through many-electron quantum wavefunctions

classification physics.chem-ph cond-mat.str-elquant-ph
keywords electronicp-clusterstatesmany-electronnitrogenasespincofactorsoxidation
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The electronic structure of the nitrogenase metal cofactors is central to nitrogen fixation. However, the P-cluster and iron molybdenum cofactor, each containing eight irons, have resisted detailed characterization of their electronic properties. Through exhaustive many-electron wavefunction simulations enabled by new theoretical methods, we report on the low-energy electronic states of the P-cluster in three oxidation states. The energy scales of orbital and spin excitations overlap, yielding a dense spectrum with features we trace to the underlying atomic states and recouplings. The clusters exist in superpositions of spin configurations with non-classical spin correlations, complicating interpretation of magnetic spectroscopies, while the charges are mostly localized from reorganization of the cluster and its surroundings. Upon oxidation, the opening of the P-cluster significantly increases the density of states, which is intriguing given its proposed role in electron transfer. These results demonstrate that many-electron simulations stand to provide new insights into the electronic structure of the nitrogenase cofactors.

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