Active mixed-valent MnO(x) water oxidation catalysts through partial oxidation (corrosion) of nanostructured MnO particles.
about
Reversible amorphization and the catalytically active state of crystalline Co3O4 during oxygen evolutionManganese oxide supported on gold/iron as a water-oxidizing catalyst in artificial photosynthetic systems.Partially Oxidized Sub-10 nm MnO Nanocrystals with High Activity for Water Oxidation Catalysis.Well-defined palladium nanoparticles supported on siliceous mesocellular foam as heterogeneous catalysts for the oxidation of water.Electrocatalytic Water Oxidation Promoted by 3 D Nanoarchitectured Turbostratic δ-MnOx on Carbon Nanotubes.Porous Nickel-Iron Oxide as a Highly Efficient Electrocatalyst for Oxygen Evolution Reaction.Reconstruction of Mini-Hollow Polyhedron Mn2O3 Derived from MOFs as a High-Performance Lithium Anode Material.Uncovering structure-activity relationships in manganese-oxide-based heterogeneous catalysts for efficient water oxidation.Iron-cobalt bimetal oxide nanorods as efficient and robust water oxidation catalysts.An Oxofluoride Catalyst Comprised of Transition Metals and a Metalloid for Application in Water Oxidation.Frontiers of water oxidation: the quest for true catalysts.A small bandgap semiconductor, p-type MnV2O6, active for photocatalytic hydrogen and oxygen production.Boosting Visible-Light-Driven Photocatalytic Hydrogen Evolution with an Integrated Nickel Phosphide-Carbon Nitride System.Nickel as a co-catalyst for photocatalytic hydrogen evolution on graphitic-carbon nitride (sg-CN): what is the nature of the active species?Surface and Structural Investigation of a MnOx Birnessite-Type Water Oxidation Catalyst Formed under Photocatalytic Conditions.Facet-dependent catalytic activity of MnO electrocatalysts for oxygen reduction and oxygen evolution reactions.Boosting Electrochemical Water Oxidation with Metal Hydroxide Carbonate Templated Prussian Blue Analogues.Ligand-Controlled Electrodeposition of Highly Intrinsically Active and Optically Transparent NiFeOx Hy Film as a Water Oxidation Electrocatalyst.A Molecular Approach to Manganese Nitride Acting as a High Performance Electrocatalyst in the Oxygen Evolution Reaction.Redox properties of birnessite from a defect perspective.Facile synthesis of sponge-like Ni3N/NC for electrocatalytic water oxidation.From a Molecular 2Fe-2Se Precursor to a Highly Efficient Iron Diselenide Electrocatalyst for Overall Water Splitting.Alkaline electrochemical water oxidation with multi-shelled cobalt manganese oxide hollow spheres.Boosting electrochemical water oxidation through replacement of Oh Co sites in cobalt oxide spinel with manganese.Direct Synthesis of Two Inorganic Catalysts on Carbon Fibres for the Electrocatalytic Oxidation of Water.Element strategy of oxygen evolution electrocatalysis based on in situ spectroelectrochemistry.Iron-Based Metal-Organic Frameworks as Catalysts for Visible Light-Driven Water Oxidation.Scalable Synthesis of Efficient Water Oxidation Catalysts: Insights into the Activity of Flame-Made Manganese Oxide Nanocrystals.Carbon for engineering of a water-oxidizing catalyst.Ultrathin nanosheets constructed CoMoO4 porous flowers with high activity for electrocatalytic oxygen evolution.Using nickel manganese oxide catalysts for efficient water oxidation.Heterogeneous catalysis.Heterogeneous water oxidation: surface activity versus amorphization activation in cobalt phosphate catalysts.Cobalt-manganese-based spinels as multifunctional materials that unify catalytic water oxidation and oxygen reduction reactions.A molecular approach to self-supported cobalt-substituted ZnO materials as remarkably stable electrocatalysts for water oxidation.A novel 3D energetic MOF of high energy content: synthesis and superior explosive performance of a Pb(ii) compound with 5,5'-bistetrazole-1,1'-diolate.Applications of ALD MnO to electrochemical water splitting.Electrochemical trapping of metastable Mn ions for activation of MnO oxygen evolution catalystsHighly Active MnO Catalysts Integrated onto Fe2O3Nanorods for Efficient Water SplittingEfficient Water Splitting Cascade Photoanodes with Ligand-Engineered MnO Cocatalysts
P2860
Q28607798-22A01CA0-45C0-41F2-A249-57EDB933D630Q31095641-1FD3F97F-6DF2-48AA-BEA7-E55A10208059Q35635721-0DF41F51-03C7-46CE-B71B-46B26593D459Q35729399-D96AA4A5-4728-48FC-99A8-E8FF0A363E60Q36414267-9C48E229-0E13-4D75-9459-32CEEFF1AB53Q37308581-C77F84D2-EB4D-4A02-B334-7C1C4E174B15Q37308877-78F7911D-4A2A-404D-ABDC-AF3FF4B23FFFQ38340377-C987B14F-0C9F-47A1-869E-657035493BDEQ38745427-D4C0F78C-CC1D-4F97-8519-016C4305AC18Q38980164-8A8E2D94-FA71-45DD-8950-CB0F61A67981Q39459214-35589BFC-7158-4057-A797-E670E5860347Q44871951-780500ED-36E5-4B70-A9D6-2ACEA8A993C0Q46435272-91580ABF-C3CC-4D71-92DF-FA8BEDD5E9E3Q46649334-042E56D0-B77F-444E-B83F-1B2CB8FD2AD5Q46685907-FFF1AA12-C28A-491C-B2BA-AF090B95CDE6Q46764876-3652866F-719B-4F50-93C8-93B629ECFE42Q47274225-07EEFACC-B5A5-4C1E-83B1-29E07F40860BQ47422618-107B5BB8-FD8E-48AB-B02F-7575CA29B10DQ47769335-C5725C99-5C06-4F3A-BF58-1AE69504319FQ47920305-585CB012-40B1-4B9E-8015-13E789F35DF9Q47929564-885F8CA9-019B-4B59-A89C-9DCF3A594579Q47982928-343E2C91-D035-462E-910B-D3F1FF850E34Q47983078-00D61C03-8F4B-4C24-A4CA-771730759D46Q47988155-E6A9FB1A-378F-40F4-9ADF-CFCF348CC238Q48215479-BD04C157-7D8D-4937-A916-24BC81EDA3C3Q50648821-266811F3-306F-47F6-91A3-EFAFC88C9587Q51565741-13A14317-5D79-4D11-86BE-CC1D26F34069Q51631745-D28C1965-666D-49EB-B8E2-513D07F748D2Q51637609-CC4946C3-30A8-47DD-AC90-6BF13D252508Q51811053-7796407E-6DB3-4AFC-8417-4FA7CD27367CQ52869432-41D941D6-A832-4410-AE13-F34F9D7C47F2Q52869595-2E877B35-95AB-4CB5-B4E9-9A46EB9734D6Q52870042-EB884D26-6C66-4C67-ADF3-ADED995B1FE0Q52872361-B977920D-8BD0-4333-92AE-6A7AD7726BFDQ52877315-6FFDA214-E42A-4DAB-BF8C-A50B54E521F5Q52976283-C8D2221E-D6E4-4330-94ED-76A8464EE949Q53243642-0AF67646-8D46-4E37-95E1-DDA0AC2DEACAQ57143671-9CC23D37-180D-4441-9F76-98FD0B8B2BF3Q57546559-F444B959-BA81-4D26-8E82-746A5B116610Q57824290-D4BC58BC-C62F-46BF-A407-D8BCECF0AF96
P2860
Active mixed-valent MnO(x) water oxidation catalysts through partial oxidation (corrosion) of nanostructured MnO particles.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
2013年學術文章
@zh-hant
name
Active mixed-valent MnO
@nl
Active mixed-valent MnO(x) wat ...... nanostructured MnO particles.
@en
type
label
Active mixed-valent MnO
@nl
Active mixed-valent MnO(x) wat ...... nanostructured MnO particles.
@en
prefLabel
Active mixed-valent MnO
@nl
Active mixed-valent MnO(x) wat ...... nanostructured MnO particles.
@en
P2093
P2860
P50
P356
P1476
Active mixed-valent MnO(x) wat ...... nanostructured MnO particles.
@en
P2093
Arindam Indra
Elham Baktash
Holger Dau
Johannes Pfrommer
Matthias Driess
P2860
P304
13206-13210
P356
10.1002/ANIE.201307543
P407
P577
2013-10-31T00:00:00Z