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Artificial photosynthesis: understanding water splitting in natureResolving the Differences Between the 1.9 Å and 1.95 Å Crystal Structures of Photosystem II: A Single Proton Relocation Defines Two Tautomeric Forms of the Water-Oxidizing Complex.Axial Ligation and Redox Changes at the Cobalt Ion in Cobalamin Bound to Corrinoid Iron-Sulfur Protein (CoFeSP) or in Solution Characterized by XAS and DFT.A Spotlight on the Compatibility between XFEL and Ab Initio Structures of the Oxygen Evolving Complex in Photosystem II.The open-cubane oxo-oxyl coupling mechanism dominates photosynthetic oxygen evolution: a comprehensive DFT investigation on O-O bond formation in the S4 state.Bicarbonate-induced redox tuning in Photosystem II for regulation and protection.Quantum mechanics/molecular mechanics simulation of the ligand vibrations of the water-oxidizing Mn4CaO5 cluster in photosystem II.Rationalizing the 2.25 Å Resolution Crystal Structure of the Water Oxidising Complex of Photosystem II in the S3 State.Interaction of methanol with the oxygen-evolving complex: atomistic models, channel identification, species dependence, and mechanistic implications.Cluster size and composition dependent water deprotonation by free manganese oxide clusters.Understanding and tuning the properties of redox-accumulating manganese helicates.Structural Changes Correlated with Magnetic Spin State Isomorphism in the S2 State of the Mn4CaO5 Cluster in the Oxygen-Evolving Complex of Photosystem II.Photosynthetic water oxidation: binding and activation of substrate waters for O-O bond formation.Energetics of proton release on the first oxidation step in the water-oxidizing enzyme.Synthetic control and empirical prediction of redox potentials for Co4O4 cubanes over a 1.4 V range: implications for catalyst design and evaluation of high-valent intermediates in water oxidation.Manipulating and quantifying spin states in solution as a function of pressure and temperature.Calcium and heterometallic manganese-calcium complexes supported by tripodal pyridine-carboxylate ligands: structural, EPR and theoretical investigations.What Mn Kβ spectroscopy reveals concerning the oxidation states of the Mn cluster in photosystem II.Electrocatalytic Water Oxidation by MnOx /C: In Situ Catalyst Formation, Carbon Substrate Variations, and Direct O2 /CO2 Monitoring by Membrane-Inlet Mass Spectrometry.Gernot Renger (1937-2013): his life, Max-Volmer Laboratory, and photosynthesis research.Solvent water interactions within the active site of the membrane type I matrix metalloproteinase.Electrochemical Water Oxidation Catalyzed by an In Situ Generated α-Co(OH)2 Film on Zeolite-Y Surface.Large-scale QM/MM calculations of the CaMn4O5 cluster in the S3 state of the oxygen evolving complex of photosystem II. Comparison between water-inserted and no water-inserted structures.Theoretical study of the EPR spectrum of the S3TyrZ• metalloradical intermediate state of the O2-evolving complex of photosystem II.Ab initio electronic structure study of a model water splitting dimer complex.Redox potential tuning by redox-inactive cations in nature's water oxidizing catalyst and synthetic analogues.Computational Modeling of Cobalt-Based Water Oxidation: Current Status and Future Challenges.A five-coordinate Mn(iv) intermediate in biological water oxidation: spectroscopic signature and a pivot mechanism for water binding.Summary and OutlookStructural models of the biological oxygen-evolving complex: achievements, insights, and challenges for biomimicryResolving the Manganese Oxidation States in the Oxygen-evolving Catalyst of Natural PhotosynthesisAlternative mechanisms for O2 release and O–O bond formation in the oxygen evolving complex of photosystem II
P2860
Q26822967-846DFA2E-0E2E-4259-9118-3869FD659567Q35616119-D20C9BAF-BCD8-4733-A997-8D54DC9C1D9BQ36069183-964DEC48-85F8-4BB2-8468-51A182E4A0F1Q36322957-8B4D5205-A403-465F-905C-A647CD8F4A05Q36373904-69E2F848-3EAE-4D4E-8A4D-3D6C177EA62DQ37379775-6C465FCC-66F8-4B56-A6F6-800FB36A91DBQ37417927-9B4327C1-D9E9-40D7-A7D2-645D9CF27967Q38605632-E8861DB8-8103-4B50-AA12-490D214D0AADQ38815732-2B884129-59E9-461A-A699-FE1C7F5E6807Q38862346-135CEE96-1ADE-43AC-9221-86D9B1D111A0Q39256235-E670349A-8535-4364-A79D-5267F16D3B2AQ40356066-15939B13-91AC-4543-A79A-EE80146BC396Q40454255-23679B7D-0EBC-40C1-9BD6-E46B1BA49ABDQ41880291-10FA7FAE-A6B8-4524-B0FF-936D0D481BFEQ42705575-C9C1C33E-822A-4F60-9D0D-643F38211C77Q46245575-A22BDC7B-EF32-43CE-8C96-56557060EDF1Q46712989-B0181A7D-A2CF-4795-810E-2ADB159B4954Q47659778-73724B9F-87C6-4090-91C7-C60344EB73BFQ47719337-30D500D3-D9C4-4A48-AEB6-FC0EA5D034D5Q47722238-EDB90745-C507-496A-9D59-EA7BD025F0FEQ47738424-7DECE43B-05AE-44DD-B996-282CA9BCB4B4Q48248360-E2547BF3-BE4C-46F7-9403-30A7B2387D30Q52705483-F3387499-2AE5-42B0-A054-22E0F73D24D0Q53099727-548FB07F-9668-4BE9-81FD-DF8A1CF1EA48Q53414578-F6C4B9A7-58CF-4DC4-B560-A536AD3B48AFQ53642078-540B69B9-A0DC-4ED4-A473-4C611B897C0CQ55232868-B32DDEF4-2D85-4406-A2F9-7CDEA5F20FD4Q55235157-DB501A2D-4499-49A5-B738-27ED2443E636Q56880569-C30D3C3C-8A99-473C-94E3-419A4BE0F213Q58009361-D4679FE5-C8AD-4639-91A3-DB7D2AF41FE3Q58009531-3BB5BE61-44F5-4C79-AE7C-908784A6C096Q59209581-9FFEF1C0-CF10-43B9-B773-0CF928E2EB33
P2860
description
2015 nî lūn-bûn
@nan
2015年の論文
@ja
2015年学术文章
@wuu
2015年学术文章
@zh
2015年学术文章
@zh-cn
2015年学术文章
@zh-hans
2015年学术文章
@zh-my
2015年学术文章
@zh-sg
2015年學術文章
@yue
2015年學術文章
@zh-hant
name
Metal oxidation states in biological water splitting.
@en
Metal oxidation states in biological water splitting.
@nl
type
label
Metal oxidation states in biological water splitting.
@en
Metal oxidation states in biological water splitting.
@nl
prefLabel
Metal oxidation states in biological water splitting.
@en
Metal oxidation states in biological water splitting.
@nl
P2860
P50
P356
P1433
P1476
Metal oxidation states in biological water splitting.
@en
P2093
Johannes Messinger
Serena DeBeer
P2860
P304
P356
10.1039/C4SC03720K
P577
2015-01-09T00:00:00Z