Hydrogenase biomimetics: Fe2(CO)4(μ-dppf)(μ-pdt) (dppf = 1,1′-bis(diphenylphosphino)ferrocene) both a proton-reduction and hydrogen oxidation catalyst

Reactions of [FeFe]-hydrogenase models involving the formation of hydrides related to proton reduction and hydrogen oxidation

(2013) Ning Wang et al.   DALTON TRANSACTIONS

Models of the iron-only hydrogenase: a comparison of chelate and bridge isomers of Fe2(CO)4{Ph2PN(R)PPh2}(μ-pdt) as proton-reduction catalysts

(2013) Shishir Ghosh et al.   DALTON TRANSACTIONS

H2 Binding and Splitting on a New-Generation [FeFe]-Hydrogenase Model Featuring a Redox-Active Decamethylferrocenyl Phosphine Ligand: A Theoretical Investigation

(2013) Claudio Greco   INORGANIC CHEMISTRY

Fluorinated models of the iron-only hydrogenase: An electrochemical study of the influence of an electron-withdrawing bridge on the proton reduction overpotential and catalyst stability

(2013) Faith Ridley et al.   JOURNAL OF ELECTROANALYTICAL CHEMISTRY

Electrochemical Hydrogen Production in Acidic Water by an Azadithiolate Bridged Synthetic Hydrogenese Mimic: Role of Aqueous Solvation in Lowering Overpotential

(2013) Subal Dey et al.   ACS Catalysis

Redox-active ligands in catalysis

(2012) Oana R. Luca et al.   CHEMICAL SOCIETY REVIEWS

A Theoretical Study on the Enhancement of Functionally Relevant Electron Transfers in Biomimetic Models of [FeFe]-Hydrogenases

(2011) Claudio Greco et al.   INORGANIC CHEMISTRY

Mild Redox Complementation Enables H2Activation by [FeFe]-Hydrogenase Models

(2011) James M. Camara et al.   JOURNAL OF THE AMERICAN CHEMICAL SOCIETY

Paramagnetic Bridging Hydrides of Relevance to Catalytic Hydrogen Evolution at Metallosulfur Centers

(2011) Aušra Jablonskytė et al.   JOURNAL OF THE AMERICAN CHEMICAL SOCIETY

Mechanistic and Physiological Implications of the Interplay among Iron–Sulfur Clusters in [FeFe]-Hydrogenases. A QM/MM Perspective

(2011) Claudio Greco et al.   JOURNAL OF THE AMERICAN CHEMICAL SOCIETY

Combining acid–base, redox and substrate binding functionalities to give a complete model for the [FeFe]-hydrogenase

(2011) James M. Camara et al.   Nature Chemistry

Mechanism of hydrogen production in [Fe–Fe]-hydrogenases: A quantum mechanics/molecular mechanics study

(2010) Steven Trohalaki et al.   INTERNATIONAL JOURNAL OF HYDROGEN ENERGY

Synthesis and structural characterization of a diiron propanedithiolate complex [(μ-PDT)Fe2(CO)5]2[(η5-Ph2PC5H4)2Fe] containing a bidentate phosphine ligand 1,1′-bis(diphenylphosphino)ferrocene

(2010) Xu-Feng Liu et al.   JOURNAL OF COORDINATION CHEMISTRY

Diphosphine Mobility at a Binuclear Metal Center: A Concerted Double Trigonal-Twist in Bis(dithiolate) Complexes [M2(CO)4(μ-dppm){μ-S(CH2)nS}] (M = Fe, Ru;n= 2, 3)

(2010) Graeme Hogarth et al.   ORGANOMETALLICS

Perspectives on How Nature Employs the Principles of Organometallic Chemistry in Dihydrogen Activation in Hydrogenases†

(2010) John C. Gordon et al.   ORGANOMETALLICS

Structural and Functional Analogues of the Active Sites of the [Fe]-, [NiFe]-, and [FeFe]-Hydrogenases†

(2009) Cédric Tard et al.   CHEMICAL REVIEWS

Models of the iron-only hydrogenase: Synthesis and protonation of bridge and chelate complexes [Fe2(CO)4{Ph2P(CH2)nPPh2}(μ-pdt)] (n=2–4) – evidence for a terminal hydride intermediate

(2008) Fatima I. Adam et al.   COMPTES RENDUS CHIMIE

Synthesis and structural characterization of the mono- and diphosphine-containing diiron propanedithiolate complexes related to [FeFe]-hydrogenases. Biomimetic H2 evolution catalyzed by (μ-PDT)Fe2(CO)4[(Ph2P)2N(n-Pr)]

(2008) Li-Cheng Song et al.   JOURNAL OF INORGANIC BIOCHEMISTRY

The Crystal Structure of [Fe]-Hydrogenase Reveals the Geometry of the Active Site

(2008) S. Shima et al.   SCIENCE