Cobalt-dithiolene complexes for the photocatalytic and electrocatalytic reduction of protons in aqueous solutions
about
Complexes of earth-abundant metals for catalytic electrochemical hydrogen generation under aqueous conditions.Experimental and Theoretical Insight into Electrocatalytic Hydrogen Evolution with Nickel Bis(aryldithiolene) Complexes as Catalysts.Photocatalytic hydrogen evolution with a self-assembling reductant-sensitizer-catalyst system.Light-driven generation of hydrogen: New chromophore dyads for increased activity based on Bodipy dye and Pt(diimine)(dithiolate) complexes.Proton-Coupled Electron Transfer: Moving Together and Charging ForwardChemical approaches to artificial photosynthesis.Photogeneration of hydrogen from water using CdSe nanocrystals demonstrating the importance of surface exchangeVersatile photocatalytic systems for H2 generation in water based on an efficient DuBois-type nickel catalyst.Solar fuels generation and molecular systems: is it homogeneous or heterogeneous catalysis?De novo design of functional proteins: Toward artificial hydrogenases.Proton reduction reaction catalyzed by homoleptic nickel bis-1,2-dithiolate complexes: Experimental and theoretical mechanistic investigations.Immobilizing Molecular Metal Dithiolene-Diamine Complexes on 2D Metal-Organic Frameworks for Electrocatalytic H2 Production.Metal-complex chromophores for solar hydrogen generation.Coordination chemistry in the design of heterogeneous photocatalysts.Computational, electrochemical, and spectroscopic studies of two mononuclear cobaloximes: the influence of an axial pyridine and solvent on the redox behaviour and evidence for pyridine coordination to cobalt(i) and cobalt(ii) metal centres.Bioinspired design of redox-active ligands for multielectron catalysis: effects of positioning pyrazine reservoirs on cobalt for electro- and photocatalytic generation of hydrogen from water.Electrocatalytic hydrogen evolution from neutral water by molecular cobalt tripyridine-diamine complexes.Parallelization of photocatalytic gas-producing reactions.Identifying intermediates of sequential electron and hydrogen loss from a dicarbonylcobalt hydride complex.A nickel complex of a conjugated bis-dithiocarbazate Schiff base for the photocatalytic production of hydrogen.Photocatalytic hydrogen production using models of the iron-iron hydrogenase active site dispersed in micellar solution.Light-Driven Hydrogen Evolution by Nickel-Substituted Rubredoxin.H2 evolution by a cobalt selenolate electrocatalyst and related mechanistic studies.A Nickel Dithiolate Water Reduction Catalyst Providing Ligand-Based Proton-Coupled Electron-Transfer Pathways.Electrocatalytic Metal-Organic Frameworks for Energy Applications.One dimensional metal dithiolene (M = Ni, Fe, Zn) coordination polymers for the hydrogen evolution reaction.New tetracobalt cluster compounds for electrocatalytic proton reduction: syntheses, structures, and reactivity.Modulation of electronic and redox properties in phenolate-rich cobalt(III) complexes and their implications for catalytic proton reduction.Photoinduced hydrogen evolution by a pentapyridine cobalt complex: elucidating some mechanistic aspects.An unexpected role of the monodentate ligand in photocatalytic hydrogen production of the pentadentate ligand-based cobalt complexes.Reactivity of Two-Electron-Reduced Boron Formazanate Compounds with Electrophiles: Facile N-H/N-C Bond Homolysis Due to the Formation of Stable Ligand Radicals.Neutral nickel(II) phthalocyanine as a stable catalyst for visible-light-driven hydrogen evolution from water.Highly functionalizable penta-coordinate iron hydrogen production catalysts with low overpotentials.A Noble-Metal-Free Nickel(II) Polypyridyl Catalyst for Visible-Light-Driven Hydrogen Production from Water.Toward Activity Origin of Electrocatalytic Hydrogen Evolution Reaction on Carbon-Rich Crystalline Coordination Polymers.Proton reduction by a nickel complex with an internal quinoline moiety for proton relay.A cobalt complex with a bioinspired molybdopterin-like ligand: a catalyst for hydrogen evolution.Towards a comprehensive insight into efficient hydrogen production by self-assembled Ru(bpy)3(2+)-polymer-Pt artificial photosystems.Photocatalytic hydrogen evolution with ruthenium polypyridine sensitizers: unveiling the key factors to improve efficiencies.Efficient photo-driven hydrogen evolution by binuclear nickel catalysts of different coordination in noble-metal-free systems.
P2860
Q30571944-71BCA7D8-1613-4A8E-8984-DE18B8DABA63Q33862134-5F35DC94-9A2D-48EF-B904-04F04084CE8AQ34755060-56D5114B-C305-4AA6-8D2B-BA32DFBFF388Q35910148-C1FB6B3E-0AA2-4597-80EB-063672A57937Q36147890-2F9437F1-72C9-4C4B-A1DC-27B34A730CAEQ36300661-781792E2-7092-4E38-A829-610303302B07Q37240394-67352466-A5A3-4839-A107-28E64958284CQ37513197-FF253D82-B4D1-4DB7-80DC-95BB32A9544BQ38060989-EECACE15-2DA1-4ED2-9321-9B04560D3F16Q38166651-9DE83FB5-4C73-4178-B031-3B37C31A198AQ38697498-FD471786-7E83-44D8-B908-C3F4D45F0B9BQ38791683-3307223A-C5CA-45C5-BF71-74704C211301Q38799696-9358F61B-95EE-4A35-9224-6180E66F9846Q39214740-BE0B4E61-B89F-4BA3-A9A6-D639308B190BQ39722723-954750C5-4334-4EC3-8C05-FB0ECEC1E517Q43588057-972E014F-E356-457E-BF7A-27C7B4A9338CQ44372478-6A7CD984-4A1A-40E3-A93E-BE5BA55BFAE5Q44856784-A85BDEFC-C893-41B5-8347-3715A45A8C04Q44939017-5CBC1F95-5645-4761-B589-BFBDC5D23193Q45016578-EB2C7F1F-A9E9-4A20-9A2B-C311394489A4Q45393022-40E702C1-BCEA-460A-8D50-E11B6F822F2FQ45940132-E133FAC0-F8E2-4D1A-96E3-BD79AE16B826Q46371571-2468EE84-6844-4B1D-A315-57ACCBD71441Q46406757-F34B630F-10AA-4706-9B06-B5F0A9F96B8FQ46687329-5D55D1F2-5182-4771-86C1-CC110C770739Q46696052-304B3395-D1A0-48FD-87CC-C3704CA40BABQ46779328-AA2015FD-24C2-4C45-AC57-310921DEF4FEQ46784480-46593C88-6713-468D-9E0E-8F9A608BB845Q46836557-9A2248D0-0A1A-42A4-8DC2-24C94AF60D0EQ46895033-4322B665-D32B-467B-B388-A8063BA6525CQ49982545-4B36587C-D9FA-4606-97A6-257F1F122935Q51571030-BB732BAD-F9E5-4E0F-BA79-07EC1BC1BE4AQ51608595-6EF07E6F-55E6-4D68-8FE6-F83E4C1EB768Q51812998-2B4A4402-2784-4620-A181-AE0D1F364AA4Q52564892-79902D2D-5495-4EC3-8F65-0B3F83DE8D6BQ52990408-F4D7AE20-2C12-4A23-BE42-DCE8AC4C909FQ52990821-5A94E51E-2E14-4F1B-BEFE-F141ACC1A5A2Q53019280-2AB96C07-B1F2-44E2-8CF2-E2810E15A54DQ53100343-3BCDA974-F33B-469C-AF3B-3E2FADE07694Q53111113-E04A7C52-F7C1-4AB4-82CD-7E34900B863F
P2860
Cobalt-dithiolene complexes for the photocatalytic and electrocatalytic reduction of protons in aqueous solutions
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh
2012年學術文章
@zh-hant
name
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@ast
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@en
type
label
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@ast
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@en
prefLabel
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@ast
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@en
P2093
P2860
P356
P1476
Cobalt-dithiolene complexes fo ...... f protons in aqueous solutions
@en
P2093
Chih-Juo Madeline Yin
Patrick L Holland
William R McNamara
P2860
P304
15594-15599
P356
10.1073/PNAS.1120757109
P407
P577
2012-06-12T00:00:00Z