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Fragments of layered manganese oxide are the real water oxidation catalyst after transformation of molecular precursor on clay.Treated Nanolayered Mn Oxide by Oxidizable Compounds: A Strategy To Improve the Catalytic Activity toward Water Oxidation.Photosynthetic water oxidation at elevated dioxygen partial pressure monitored by time-resolved X-ray absorption measurements.A high-valent heterobimetallic [Cu(III)(μ-O)2Ni(III)]2+ core with nucleophilic oxo groups.Room-Temperature Energy-Sampling Kβ X-ray Emission Spectroscopy of the Mn4Ca Complex of Photosynthesis Reveals Three Manganese-Centered Oxidation Steps and Suggests a Coordination Change Prior to O2 Formation.Merging Structural Information from X-ray Crystallography, Quantum Chemistry, and EXAFS Spectra: The Oxygen-Evolving Complex in PSII.Recent developments in research on water oxidation by photosystem II.Drought-induced modifications of photosynthetic electron transport in intact leaves: analysis and use of neural networks as a tool for a rapid non-invasive estimation.Principles, efficiency, and blueprint character of solar-energy conversion in photosynthetic water oxidation.Inhibitory and non-inhibitory NH3-binding at the water-oxidizing manganese complex of photosystem II suggests possible sites and rearrangement mode of substrate-water molecules.Active mixed-valent MnO(x) water oxidation catalysts through partial oxidation (corrosion) of nanostructured MnO particles.Iron-doped nickel oxide nanocrystals as highly efficient electrocatalysts for alkaline water splitting.Cyanamide route to calcium-manganese oxide foams for water oxidation.Cobalt-oxo core of a water-oxidizing catalyst film.Sequential and Coupled Proton and Electron Transfer Events in the S2 → S3 Transition of Photosynthetic Water Oxidation Revealed by Time-Resolved X-ray Absorption Spectroscopy.Electrosynthesis of Biomimetic Manganese-Calcium Oxides for Water Oxidation Catalysis--Atomic Structure and Functionality.Atomistic Texture of Amorphous Manganese Oxides for Electrochemical Water Splitting Revealed by Ab Initio Calculations Combined with X-ray Spectroscopy.Heterogeneous water oxidation: surface activity versus amorphization activation in cobalt phosphate catalysts.Water oxidation by electrodeposited cobalt oxides--role of anions and redox-inert cations in structure and function of the amorphous catalyst.Nickel-oxido structure of a water-oxidizing catalyst film.Helical cobalt borophosphates to master durable overall water-splittingElectrosynthesis, functional, and structural characterization of a water-oxidizing manganese oxideSimultaneous analysis of prompt and delayed chlorophyll a fluorescence in leaves during the induction period of dark to light adaptationKinetics of delayed chlorophyll a fluorescence registered in milliseconds time rangePreservation of photosynthetic electron transport from senescence-induced inactivation in primary leaves after decapitation and defoliation of bean plantsThe D1-D61N mutation in Synechocystis sp. PCC 6803 allows the observation of pH-sensitive intermediates in the formation and release of O₂ from photosystem IIScreen-printed calcium-birnessite electrodes for water oxidation at neutral pH and an "electrochemical harriman series"Water oxidation by amorphous cobalt-based oxides: volume activity and proton transfer to electrolyte basesWater oxidation by manganese oxides formed from tetranuclear precursor complexes: the influence of phosphate on structure and activityKα X-ray Emission Spectroscopy on the Photosynthetic Oxygen-Evolving Complex Supports Manganese Oxidation and Water Binding in the S3 StateA synthetic manganese-calcium cluster similar to the catalyst of Photosystem II: challenges for biomimetic water oxidation
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Q30814635-3EE4D36D-AF65-4878-B7D9-674870AEE8FBQ31122298-6715BDB1-D9A2-4538-928C-9C4B8BE98B97Q33382972-A5D83859-1850-4DF9-A3BD-D8275F6B4728Q33855511-D515087C-EDEE-46D0-ACFD-DC80EE7C97D9Q36067602-73AAD995-E577-4B06-A75D-5D7DDA9DA328Q36144797-EB95A94C-7B9B-46C1-AC23-C31402500327Q37990276-66ED8044-55D5-43C3-B4A5-CFDBAF180D30Q39027031-9F1BABA4-B3D6-4667-847D-BEF3DC8D834DQ39929932-1EABE722-2016-4045-89F4-CDB38E1949E7Q43033354-53E2C68C-1F62-4F76-A245-EE52D1FF9DA9Q43540281-E4AFCEDC-1CC2-44A1-9BD8-E4E2EC667CC1Q46750167-0B087817-6C55-4063-B64B-9BEFAF83F9ADQ46963020-2FE5E92B-A5CE-49EA-8D39-20B2E8199B50Q47871993-4F06950E-7719-4EBE-86A1-6EA0CC151019Q48138546-AFD281EB-FD32-4F14-BD1C-E6D8593B237FQ48637121-BBB15DD9-3F9F-417E-87EE-6A04F9DC81D9Q52863762-A64D35D6-9B2D-443E-837D-F0E497E2D0AEQ52870042-71ECBB92-D204-46D9-8B4A-2E67646BE71AQ52889710-56793A3F-FD98-4F8A-9D82-362ACF33DC1CQ52892585-5242D282-BCA9-448D-9A5A-EBF87673DDF8Q60028123-D8ADD765-966A-4794-9442-B6603CBD8518Q63413858-015F0CD4-1897-4867-9B5C-AE72B4310206Q79201952-220F957B-7A15-4186-A557-7D2ED2AE6202Q80949005-A3E79B2A-80FE-479B-A878-F5A7344DDAE9Q81542126-4FCF048C-7D88-41DA-A29B-112AF205C9D3Q83106329-91561C26-E8B7-4B8E-AFD9-DFD3D3B47732Q85856899-CBC4C6DE-E4FD-4029-86DE-8D5F7127721BQ87141216-DF7707E5-B9C6-4699-B167-48F9BDC5CFF2Q87475452-395928C1-A680-4556-A32C-4FCCFC600F42Q90686662-5F8EC08D-32CA-44EC-BA6A-69F5DD218611Q91855613-C7A4C110-D19D-454A-A185-332C5A6EB651
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Ivelina Zaharieva
@ast
Ivelina Zaharieva
@en
Ivelina Zaharieva
@es
Ivelina Zaharieva
@nl
Ivelina Zaharieva
@sl
type
label
Ivelina Zaharieva
@ast
Ivelina Zaharieva
@en
Ivelina Zaharieva
@es
Ivelina Zaharieva
@nl
Ivelina Zaharieva
@sl
prefLabel
Ivelina Zaharieva
@ast
Ivelina Zaharieva
@en
Ivelina Zaharieva
@es
Ivelina Zaharieva
@nl
Ivelina Zaharieva
@sl
P106
P31
P496
0000-0002-4745-5307