Powering the future of molecular artificial photosynthesis with light-harvesting metallosupramolecular dye assemblies.
about
Biosolar cells: global artificial photosynthesis needs responsive matrices with quantum coherent kinetic control for high yieldPhotosynthesis at the forefront of a sustainable life.Substitution Effects on the Photoinduced Charge Transfer Properties of Novel Perylene-3,4,9,10-tetracarboxylic Acid Derivatives.Cascade exciton-pumping engines with manipulated speed and efficiency in light-harvesting porous π-network films.AIEgens for dark through-bond energy transfer: design, synthesis, theoretical study and application in ratiometric Hg2+ sensingCascaded exciton energy transfer in a monolayer semiconductor lateral heterostructure assisted by surface plasmon polariton.Photocatalytic hydrogen evolution with a self-assembling reductant-sensitizer-catalyst system.Small-peptide-based organogel kit: towards the development of multicomponent self-sorting organogels.Ultrafast photo-induced ligand solvolysis of cis-[Ru(bipyridine)2(nicotinamide)2](2+): experimental and theoretical insight into its photoactivation mechanism.An allosteric photoredox catalyst inspired by photosynthetic machineryPhotocurrent generation through charge-transfer processes in noncovalent perylenediimide/DNA complexes.A computational mechanistic investigation of hydrogen production in water using the [Rh(III)(dmbpy)2Cl2](+)/[Ru(II)(bpy)3](2+)/ascorbic acid photocatalytic system.A Structural Model for a Self-Assembled Nanotube Provides Insight into Its Exciton Dynamics.Ultrafast charge transfer dynamics in supramolecular Pt(II) donor-bridge-acceptor assemblies: the effect of vibronic coupling.Boron Difluoride Complexes of Expanded N-Confused Calix[n]phyrins That Demonstrate Unique Luminescent and Lasing Properties.Charge localization in a diamine cation provides a test of energy functionals and self-interaction correctionRu(II)-diimine functionalized metalloproteins: From electron transfer studies to light-driven biocatalysis.Hydrogen photogeneration promoted by efficient electron transfer from iridium sensitizers to colloidal MoS2 catalysts.Material science lesson from the biological photosystemShape- and size-controlled nanomaterials for artificial photosynthesis.25th anniversary article: reversible and adaptive functional supramolecular materials: "noncovalent interaction" matters.Oligo(phenylenevinylene) hybrids and self-assemblies: versatile materials for excitation energy transfer.One-dimension-based spatially ordered architectures for solar energy conversion.Beta-Sheet-Forming, Self-Assembled Peptide Nanomaterials towards Optical, Energy, and Healthcare Applications.A multicomponent molecular approach to artificial photosynthesis - the role of fullerenes and endohedral metallofullerenes.Metal-complex chromophores for solar hydrogen generation.Excited state relaxation processes of H2-evolving Ru-Pd supramolecular photocatalysts containing a linear or non-linear bridge: a DFT and TDDFT study.Challenges and Perspectives in Designing Artificial Photosynthetic Systems.Light-Harvesting Antennae Based on Silicon Nanocrystals.Enhancing Photocatalytic Hydrogen Generation: the Impact of the Peripheral Ligands in Ru/Pd and Ru/Pt Complexes.Excited-State Dynamics of a Two-Photon-Activatable Ruthenium Prodrug.Chemical designs of functional photoactive molecular assemblies.Recent progress in the development of bimetallic photocatalysts for hydrogen generation.Coupling photocatalysis and redox biocatalysis toward biocatalyzed artificial photosynthesis.Furan- and Thiophene-Based Auxochromes Red-shift Chlorin Absorptions and Enable Oxidative Chlorin Polymerizations.Chitosan confinement enhances hydrogen photogeneration from a mimic of the diiron subsite of [FeFe]-hydrogenase.Enhancement of Solar Fuel Production Schemes by Using a Ru,Rh,Ru Supramolecular Photocatalyst Containing Hydroxide Labile Ligands.Water reduction systems associated with homoleptic cyclometalated iridium complexes of various 2-phenylpyridines.Covalent post-assembly modification in metallosupramolecular chemistry.A Heterogeneous Photocatalytic Hydrogen Evolution Dyad: [(tpy.
P2860
Q26866930-C28614D9-A29D-46CB-AC1D-A24DEB1D21CFQ28658293-63D4B875-5613-4785-8356-E9E7151855A9Q30101131-7EAFC1A5-57AB-4B01-8D77-8566B432DE76Q33559558-C94080F0-773C-4A47-8973-6FF710121262Q33583752-1808FCF5-E81C-46DF-AE8D-EE63724DD386Q33835297-50C0A820-F257-40EA-82B0-26CE373861EBQ34755060-C025D4F0-1183-49C3-80E6-89E9EB4D89F7Q35033976-49CFA8DE-454E-40AA-9FEC-0FDD5E6E7F01Q35212794-B79FB5FC-04BF-4044-8805-C269BF8584B7Q35311727-3F77DE77-6057-4CEF-9AB3-500E780B65F2Q35580106-FC146979-AD7B-4EA7-BFD7-705EE5C077F7Q35585746-B217C137-62AB-4DF9-8E2C-8166ABF0BFB0Q35766865-FABAE9F0-787D-4874-8E7E-0036F44E0519Q35795937-192815F1-9E22-433A-9A42-40D7DE1C1FE5Q36105248-0BF08321-1D01-4982-B8DD-EAB0C4FD1F48Q36704836-EA8DABA1-0FF6-4A64-9E2A-4B9D7DB9A228Q36731016-AD9E6C78-07D8-4241-9641-37AA26DF7A54Q37570972-1E7D9F65-046D-4144-9933-AF7874F33AEBQ37610377-74C0DDFD-73CD-4AEF-81D6-E1177B1CF535Q38128542-6CD9054F-D716-4B59-8C94-297389BB31D3Q38137885-2CAABC51-47BF-4E98-9501-31D716736EC5Q38189615-ACC56647-EACB-4A88-9D0B-D71D5122B1D2Q38412933-8300EABF-A42F-46D1-9655-FBE80A600542Q38452137-C3870C4E-A7D0-482A-8F3B-A9EE2E4D7E00Q38690288-F913E40E-5EE2-466B-AF64-C6788CDEE59EQ38799696-97983D36-CC37-4155-8B6A-2191FA8AFBE6Q38829180-9C1B987A-453D-41F5-A3D7-DE1C458C9B06Q38872455-F954F79E-29AD-42AE-B7E7-1BA37CF0279EQ38940378-FF27759F-0A10-4AAD-B811-5A60F26305CDQ38962537-791A5CF0-54FB-41CD-A594-3FFD08D5177EQ39144378-6CE42E62-58BF-4FD7-BB8D-FD50AE02FD58Q39257174-4C7CC42F-6E1F-483F-B982-96E21F97FCC8Q39331881-B782EE90-7AEA-4B95-88AF-BD7E783AB298Q39462460-3C6D891A-6E7A-4C3A-BECB-B91623D2CA26Q42291072-B9F607DF-9878-460B-B294-65942D47FEC7Q43795620-1E7B15CB-521D-4DB6-B6F8-C0AEA08C075EQ45020093-36E9A619-EFAC-4BA1-8D63-0C64370925B8Q46008360-63C78096-F509-40D3-AC88-11E34C308FD0Q46260658-32DAB1C5-8CB1-4FD4-873C-26888556401FQ46495743-B4373153-1A17-4A46-8BC7-010485016BC1
P2860
Powering the future of molecular artificial photosynthesis with light-harvesting metallosupramolecular dye assemblies.
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Powering the future of molecul ...... supramolecular dye assemblies.
@en
type
label
Powering the future of molecul ...... supramolecular dye assemblies.
@en
prefLabel
Powering the future of molecul ...... supramolecular dye assemblies.
@en
P2860
P356
P1476
Powering the future of molecul ...... supramolecular dye assemblies.
@en
P2093
Peter D Frischmann
P2860
P304
P356
10.1039/C2CS35223K
P577
2012-07-31T00:00:00Z