2024
Water Ligands Regulate the Redox Leveling Mechanism of the Oxygen-Evolving Complex of the Photosystem II
Liu J, Yang K, Long Z, Armstrong W, Brudvig G, Batista V. Water Ligands Regulate the Redox Leveling Mechanism of the Oxygen-Evolving Complex of the Photosystem II. Journal Of The American Chemical Society 2024, 146: 15986-15999. PMID: 38833517, DOI: 10.1021/jacs.4c02926.Peer-Reviewed Original ResearchProton-coupled electron transferOxygen-evolving complexWater insertionWater ligandsCatalytic cycleMolecular dynamicsO-O bondQuantum mechanics/molecular mechanicsConformational changesFree energy changeLigand environmentElectron transferLigand exchangePhotosystem IIOxygen evolutionWater binding mechanismsEnergy changeLigandBinding mechanismAqueous environmentRedoxWater bindingLigand bindingCatalystIsomerization
2023
Redox leveling of the Kok cycle of photosystem II established by water ligand binding to the oxygen evolving complex
Liu J, Yang K, Brudvig G, Batista V. Redox leveling of the Kok cycle of photosystem II established by water ligand binding to the oxygen evolving complex. Biophysical Journal 2023, 122: 199a-200a. DOI: 10.1016/j.bpj.2022.11.1210.Peer-Reviewed Original Research
2015
Triplet Oxygen Evolution Catalyzed by a Biomimetic Oxomanganese Complex: Functional Role of the Carboxylate Buffer
Rivalta I, Yang K, Brudvig G, Batista V. Triplet Oxygen Evolution Catalyzed by a Biomimetic Oxomanganese Complex: Functional Role of the Carboxylate Buffer. ACS Catalysis 2015, 5: 2384-2390. DOI: 10.1021/acscatal.5b00048.Peer-Reviewed Original ResearchOxomanganese complexesTriplet oxygenOxygen evolutionWater splittingCatalytic oxygen evolutionO bond formationBiomimetic oxomanganese complexesNucleophilic water moleculeUnderlying reaction mechanismGreen plant chloroplastsPhotosynthetic oxygen evolutionWater ligandsCarboxylate ligandsInorganic coreMn complexesSuperoxo speciesNoninnocent roleCarboxylate groupsWater moleculesSubstrate waterBond formationSynthetic complexesCarboxylate buffersNucleophilic attackRedox potential
2009
Deposition of an oxomanganese water oxidation catalyst on TiO 2 nanoparticles : computational modeling, assembly and characterization
Li G, Sproviero E, Snoeberger R, Iguchi N, Blakemore J, Crabtree R, Brudvig G, Batista V. Deposition of an oxomanganese water oxidation catalyst on TiO 2 nanoparticles : computational modeling, assembly and characterization. Energy & Environmental Science 2009, 2: 230-238. DOI: 10.1039/b818708h.Peer-Reviewed Original ResearchWater oxidation catalystsOxidation catalystTiO2 nanoparticlesUV-visible spectroscopyTiO 2 nanoparticlesMixed valence stateAmorphous TiO2 nanoparticlesWater ligandsElectrochemical studiesElectrochemical measurementsEPR spectroscopySurface complexesMimic photosynthesisDirect adsorptionSitu synthesisTiO2 surfaceSuccessful attachmentEPR dataNanoparticlesCatalystSolar cellsSpectroscopyComputational modelingAdsorptionEPR
2008
Functional Manganese Model Chemistry Relevant to the Oxygen-Evolving Complex of Photosystem II: Oxidation of a Mn(III,IV) Complex Coupled to Deprotonation of a Terminal Water Ligand
Cady C, Crabtree R, Brudvig G. Functional Manganese Model Chemistry Relevant to the Oxygen-Evolving Complex of Photosystem II: Oxidation of a Mn(III,IV) Complex Coupled to Deprotonation of a Terminal Water Ligand. 2008, 377-381. DOI: 10.1007/978-1-4020-6709-9_85.Peer-Reviewed Original ResearchTerminal water ligandsWater ligandsDinuclear manganese complexPH-dependent oxidationOxygen-Evolving ComplexRedox stepsManganese complexesRedox levelingElectron transferModel chemistryTerminal waterLigandsOxidationDeprotonationComplex occursComplexesPhotosystem IIChemistryProtonsMVPHWaterNarrow rangeTransfer