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Leslie Vogt, M. Ertem, R. Pal, G. Brudvig, V. Batista (2015)
Computational insights on crystal structures of the oxygen-evolving complex of photosystem II with either Ca(2+) or Ca(2+) substituted by Sr(2+).Biochemistry, 54 3
Hong Lin, Yehui Zhang, Gang Wang, Jianbao Li (2012)
Cobalt-based layered double hydroxides as oxygen evolving electrocatalysts in neutral electrolyteFrontiers of Materials Science, 6
Bryan Hunter, James Blakemore, Mark Deimund, H. Gray, J. Winkler, A. Müller (2014)
Highly active mixed-metal nanosheet water oxidation catalysts made by pulsed-laser ablation in liquids.Journal of the American Chemical Society, 136 38
Ming Gong, Yanguang Li, Hailiang Wang, Yongye Liang, J. Wu, Jigang Zhou, Jian Wang, T. Regier, F. Wei, H. Dai (2013)
An advanced Ni-Fe layered double hydroxide electrocatalyst for water oxidation.Journal of the American Chemical Society, 135 23
J. Savéant (2008)
Molecular catalysis of electrochemical reactions. Mechanistic aspects.Chemical reviews, 108 7
V. Balzani, A. Credi, M. Venturi (2008)
Photochemical conversion of solar energy.ChemSusChem, 1 1-2
Karin Young, L. Martini, R. Milot, Robert Snoeberger, V. Batista, C. Schmuttenmaer, R. Crabtree, G. Brudvig (2012)
Light-driven water oxidation for solar fuels.Coordination chemistry reviews, 256 21-22
T. Meyer (2008)
Catalysis: The art of splitting waterNature, 451
James Blakemore, R. Crabtree, G. Brudvig (2015)
Molecular Catalysts for Water Oxidation.Chemical reviews, 115 23
P. Beaudot, M. Roy, J. Besse (2004)
Intercalation of noble metal complexes in LDH compoundsJournal of Solid State Chemistry, 177
M. Kärkäs, O. Verho, Eric Johnston, B. Åkermark (2014)
Artificial photosynthesis: molecular systems for catalytic water oxidation.Chemical reviews, 114 24
Tamara Posati, F. Costantino, L. Latterini, M. Nocchetti, M. Paolantoni, L. Tarpani (2012)
New insights on the incorporation of lanthanide ions into nanosized layered double hydroxides.Inorganic chemistry, 51 24
A. Savini, Alberto Bucci, M. Nocchetti, R. Vivani, H. Idriss, A. Macchioni (2015)
Activity and Recyclability of an Iridium–EDTA Water Oxidation Catalyst Immobilized onto Rutile TiO2ACS Catalysis, 5
K. Joya, N. Subbaiyan, F. D’Souza, H. Groot (2012)
Surface-immobilized single-site iridium complexes for electrocatalytic water splitting.Angewandte Chemie, 51 38
M. Bastianini, D. Costenaro, C. Bisio, L. Marchese, U. Costantino, R. Vivani, M. Nocchetti (2012)
On the intercalation of the iodine-iodide couple on layered double hydroxides with different particle sizes.Inorganic chemistry, 51 4
F. Evangelisti, R. Moré, Florian Hodel, S. Luber, G. Patzke (2015)
3d-4f {Co(II)3Ln(OR)4} Cubanes as Bio-Inspired Water Oxidation Catalysts.Journal of the American Chemical Society, 137 34
N. Lewis (2001)
Light work with waterNature, 414
Zuofeng Chen, Javier Concepcion, Xiangqian Hu, Weitao Yang, P. Hoertz, T. Meyer (2010)
Concerted O atom–proton transfer in the O—O bond forming step in water oxidationProceedings of the National Academy of Sciences, 107
Emily Tsui, Rosalie Tran, J. Yano, T. Agapie (2013)
Redox-Inactive Metals Modulate the Reduction Potential in Heterometallic Manganese-Oxido ClustersNature chemistry, 5
Yan Gao, Xin Ding, Jianhui Liu, Lei Wang, Zhongkai Lu, Lin Li, Licheng Sun (2013)
Visible light driven water splitting in a molecular device with unprecedentedly high photocurrent density.Journal of the American Chemical Society, 135 11
A. Bail (2005)
Whole powder pattern decomposition methods and applications: A retrospectionPowder Diffraction, 20
F. Osterloh (2008)
Inorganic Materials as Catalysts for Photochemical Splitting of WaterChemistry of Materials, 20
Yeob Lee, Jung-Hoon Choi, H. Jeon, K. Choi, J. Lee, J. Kang (2011)
Titanium-embedded layered double hydroxides as highly efficient water oxidation photocatalysts under visible lightEnergy and Environmental Science, 4
Sang Kim, Yeob Lee, Dong Lee, J. Lee, J. Kang (2014)
Efficient Co–Fe layered double hydroxide photocatalysts for water oxidation under visible lightJournal of Materials Chemistry, 2
F. Cavani, F. Trifiró, A. Vaccari (1991)
Hydrotalcite-type anionic clays: Preparation, properties and applications.Catalysis Today, 11
U. Costantino, F. Marmottini, M. Nocchetti, R. Vivani (1998)
New Synthetic Routes to Hydrotalcite-Like Compounds − Characterisation and Properties of the Obtained MaterialsEuropean Journal of Inorganic Chemistry, 1998
Qiang Wang, D. O′Hare (2012)
Recent advances in the synthesis and application of layered double hydroxide (LDH) nanosheets.Chemical reviews, 112 7
A. Parent, Timothy Brewster, W. Wolf, R. Crabtree, G. Brudvig (2012)
Sodium periodate as a primary oxidant for water-oxidation catalysts.Inorganic chemistry, 51 11
A. Kudo, Y. Miseki (2009)
Heterogeneous photocatalyst materials for water splitting.Chemical Society reviews, 38 1
Fang Song, Xile Hu (2014)
Exfoliation of layered double hydroxides for enhanced oxygen evolution catalysisNature Communications, 5
J. Vrettos, Daniel Stone, G. Brudvig (2001)
Quantifying the ion selectivity of the Ca2+ site in photosystem II: evidence for direct involvement of Ca2+ in O2 formation.Biochemistry, 40 26
Zoel Codolà, João Cardoso, B. Royo, M. Costas, J. Lloret‐Fillol (2013)
Highly effective water oxidation catalysis with iridium complexes through the use of NaIO4.Chemistry, 19 22
Ye Zhang, B. Cui, Chunsong Zhao, Hong Lin, Jianbao Li (2013)
Co-Ni layered double hydroxides for water oxidation in neutral electrolyte.Physical chemistry chemical physics : PCCP, 15 19
Bryan Hunter, W. Hieringer, J. Winkler, H. Gray, A. Müller (2016)
Effect of interlayer anions on [NiFe]-LDH nanosheet water oxidation activityEnergy and Environmental Science, 9
G. Renger (2007)
Oxidative photosynthetic water splitting: energetics, kinetics and mechanismPhotosynthesis Research, 92
I. Corbucci, Ana Petronilho, H. Müller‐Bunz, L. Rocchigiani, M. Albrecht, A. Macchioni (2015)
Substantial Improvement of Pyridine-Carbene Iridium Water Oxidation Catalysts by a Simple Methyl-to-Octyl SubstitutionACS Catalysis, 5
Charles McCrory, Suho Jung, J. Peters, T. Jaramillo (2013)
Benchmarking heterogeneous electrocatalysts for the oxygen evolution reaction.Journal of the American Chemical Society, 135 45
Cláudia Silva, Y. Bouizi, V. Fornés, H. García (2009)
Layered double hydroxides as highly efficient photocatalysts for visible light oxygen generation from water.Journal of the American Chemical Society, 131 38
N. Lewis, D. Nocera (2006)
Powering the planet: Chemical challenges in solar energy utilizationProceedings of the National Academy of Sciences, 103
U. Costantino, R. Vivani, M. Bastianini, F. Costantino, M. Nocchetti (2014)
Ion exchange and intercalation properties of layered double hydroxides towards halide anions.Dalton transactions, 43 30
Xiaoxin Zou, A. Goswami, T. Asefa (2013)
Efficient noble metal-free (electro)catalysis of water and alcohol oxidations by zinc-cobalt layered double hydroxide.Journal of the American Chemical Society, 135 46
F. Basile, G. Fornasari, M. Gazzano, A. Vaccari (2000)
Synthesis and thermal evolution of hydrotalcite-type compounds containing noble metalsApplied Clay Science, 16
J. Woods, S. Bernhard, M. Albrecht (2014)
Recent Advances in the Field of Iridium‐Catalyzed Molecular Water Oxidation
Bei Li, Yufei Zhao, Shitong Zhang, W. Gao, Min Wei (2013)
Visible-light-responsive photocatalysts toward water oxidation based on NiTi-layered double hydroxide/reduced graphene oxide composite materials.ACS applied materials & interfaces, 5 20
Stafford Sheehan, Julianne Thomsen, Ulrich Hintermair, R. Crabtree, G. Brudvig, C. Schmuttenmaer (2015)
A molecular catalyst for water oxidation that binds to metal oxide surfacesNature Communications, 6
Si-Min Xu, T. Pan, Yibo Dou, Hong Yan, Shitong Zhang, Fanyu Ning, Wenying Shi, Min Wei (2015)
Theoretical and Experimental Study on MIIMIII-Layered Double Hydroxides as Efficient Photocatalysts toward Oxygen Evolution from WaterJournal of Physical Chemistry C, 119
A. Macchioni (2014)
Homogeneous and heterogenized iridium water oxidation catalysts, 9176
Ming Gong, H. Dai (2014)
A mini review of NiFe-based materials as highly active oxygen evolution reaction electrocatalystsNano Research, 8
R. Shannon (1976)
Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenidesActa Crystallographica Section A, 32
Cheng Wang, Jin-Liang Wang, Wenbin Lin (2012)
Elucidating molecular iridium water oxidation catalysts using metal-organic frameworks: a comprehensive structural, catalytic, spectroscopic, and kinetic study.Journal of the American Chemical Society, 134 48
Herein it is shown that hydrotalcite‐like compounds (HTlcs), doped with a suitably reactive metal, can efficiently act as water oxidation catalysts. As a case study, a ternary HTlc of formula [Zn0.667Al0.306Ir0.027(OH)2]Cl0.333⋅0.6 H2O, in which iridium is homogeneously distributed into the octahedral sites of brucite‐type sheets, was prepared and tested as a heterogeneous water oxidation catalyst, using NaIO4 as a sacrificial oxidant. This HTlc showed excellent performance in terms of turnover frequency (up to 113 min−1), turnover number (>11 900), stability and recyclability.
ChemPlusChem – Wiley
Published: Oct 1, 2016
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