| 1 | Activation of Coq6p, a FAD Monooxygenase Involved in Coenzyme Q Biosynthesis, by Adrenodoxin Reductase/Ferredoxin | 2.7 | 0 | Citations (PDF) |
| 2 | Smart Electrode Surfaces by Electrolyte Immobilization for Electrocatalytic CO<sub>2</sub> Conversion | 15.7 | 19 | Citations (PDF) |
| 3 | Activation of Coq6p, a FAD Monooxygenase Involved in Coenzyme Q Biosynthesis, by Adrenodoxin Reductase/Ferredoxin | 2.7 | 0 | Citations (PDF) |
| 4 | Zr-Based MOF-545 Metal–Organic Framework Loaded with Highly Dispersed Small Size Ni Nanoparticles for CO<sub>2</sub> Methanation | 8.1 | 21 | Citations (PDF) |
| 5 | An organic O donor for biological hydroxylation reactions | 7.5 | 4 | Citations (PDF) |
| 6 | Visible-Light-Driven Carbon Dioxide Reduction Catalyzed by Iron Schiff-Base Complexes | 12.7 | 11 | Citations (PDF) |
| 7 | Identification of 2‐methylthio‐methylenethio‐N6‐(cis‐4‐hydroxyisopentenyl)‐adenosine (msms2io6A37) as a novel modification at adenosine 37 of tRNAs from Salmonella typhimurium. | 2.7 | 1 | Citations (PDF) |
| 8 | Light-Driven Hydrogen Evolution Reaction Catalyzed by a Molybdenum–Copper Artificial Hydrogenase | 15.7 | 10 | Citations (PDF) |
| 9 | Acidic Electroreduction of CO<sub>2</sub> to Multi-Carbon Products with CO<sub>2</sub> Recovery and Recycling from Carbonate | 17.5 | 51 | Citations (PDF) |
| 10 | Tuning Selectivity of Acidic Carbon Dioxide Electrolysis via Surface Modification | 6.9 | 24 | Citations (PDF) |
| 11 | Silver and Copper Nitride Cooperate for CO Electroreduction to Propanol | 14.9 | 28 | Citations (PDF) |
| 12 | Designing a Zn–Ag Catalyst Matrix and Electrolyzer System for CO<sub>2</sub> Conversion to CO and Beyond | 24.4 | 67 | Citations (PDF) |
| 13 | Gas diffusion electrodes, reactor designs and key metrics of low-temperature CO2 electrolysers | 50.4 | 520 | Citations (PDF) |
| 14 | From Nickel Foam to Highly Active NiFe‐based Oxygen Evolution Catalysts | 3.0 | 8 | Citations (PDF) |
| 15 | Understanding the Photocatalytic Reduction of CO<sub>2</sub>with Heterometallic Molybdenum(V) Phosphate Polyoxometalates in Aqueous Media | 12.7 | 50 | Citations (PDF) |
| 16 | Keeping sight of copper in single-atom catalysts for electrochemical carbon dioxide reduction | 14.2 | 113 | Citations (PDF) |
| 17 | Molecular Inhibition for Selective CO<sub>2</sub> Conversion | 14.9 | 46 | Citations (PDF) |
| 18 | Molecular Inhibition for Selective CO<sub>2</sub> Conversion | 1.5 | 4 | Citations (PDF) |
| 19 | Electrochemical CO<sub>2</sub> reduction on Cu single atom catalyst and Cu nanoclusters: an <i>ab initio</i> approach | 2.8 | 6 | Citations (PDF) |
| 20 | Origin of the Boosting Effect of Polyoxometalates in Photocatalysis: The Case of CO<sub>2</sub> Reduction by a Rh-Containing Metal–Organic Framework | 12.7 | 58 | Citations (PDF) |
| 21 | Selective Ethylene Production from CO<sub>2</sub> and CO Reduction via Engineering Membrane Electrode Assembly with Porous Dendritic Copper Oxide | 8.1 | 29 | Citations (PDF) |
| 22 | Electrocatalytic metal hydride generation using CPET mediators | 34.3 | 120 | Citations (PDF) |
| 23 | Unveiling the mechanism of the photocatalytic reduction of CO<sub>2</sub>to formate promoted by porphyrinic Zr-based metal–organic frameworks | 9.3 | 41 | Citations (PDF) |
| 24 | Highly Selective Copper-Based Catalysts for Electrochemical Conversion of Carbon Monoxide to Ethylene Using a Gas-Fed Flow Electrolyzer | 12.7 | 22 | Citations (PDF) |
| 25 | Formate Dehydrogenase Mimics as Catalysts for Carbon Dioxide Reduction | 4.4 | 12 | Citations (PDF) |
| 26 | CO<sub>2</sub> Electroreduction in Water with a Heterogenized C-Substituted Nickel Cyclam Catalyst | 4.6 | 8 | Citations (PDF) |
| 27 | Electrocatalytic Conversion of CO<sub>2</sub> to Formate at Low Overpotential by Electrolyte Engineering in Model Molecular Catalysis | 6.3 | 18 | Citations (PDF) |
| 28 | Solar‐Driven Electrochemical CO<sub>2</sub> Reduction with Heterogeneous Catalysts | 22.4 | 102 | Citations (PDF) |
| 29 | Structural Evidence for a [4Fe‐5S] Intermediate in the Non‐Redox Desulfuration of Thiouracil | 1.5 | 0 | Citations (PDF) |
| 30 | Structural Evidence for a [4Fe‐5S] Intermediate in the Non‐Redox Desulfuration of Thiouracil | 14.9 | 23 | Citations (PDF) |
| 31 | Artificial maturation of [FeFe] hydrogenase in a redox polymer film | 4.2 | 6 | Citations (PDF) |
| 32 | Electrochemical CO<sub>2</sub> Reduction to Ethanol with Copper-Based Catalysts | 17.5 | 216 | Citations (PDF) |
| 33 | Coupling Electrocatalytic CO<sub>2</sub> Reduction with Thermocatalysis Enables the Formation of a Lactone Monomer | 6.3 | 21 | Citations (PDF) |
| 34 | Iron–sulfur biology invades tRNA modification: the case of U34 sulfuration | 16.3 | 31 | Citations (PDF) |
| 35 | Benchmarking of oxygen evolution catalysts on porous nickel supportsJoule, 2021, 5, 1281-1300 | 23.4 | 132 | Citations (PDF) |
| 36 | Advancing the Anode Compartment for Energy Efficient CO<sub>2</sub> Reduction at Neutral pH | 3.0 | 18 | Citations (PDF) |
| 37 | An enzymatic activation of formaldehyde for nucleotide methylation | 14.2 | 20 | Citations (PDF) |
| 38 | Bimetallic effects on Zn-Cu electrocatalysts enhance activity and selectivity for the conversion of CO2 to CO | 6.3 | 78 | Citations (PDF) |
| 39 | Les scénarios énergétiques à l’épreuve du stockage des énergies intermittentes | 0.7 | 5 | Citations (PDF) |
| 40 | Carbon Dioxide Reduction: A Bioinspired Catalysis Approach | 17.7 | 39 | Citations (PDF) |
| 41 | Structural and Functional Characterization of 4‐Hydroxyphenylacetate 3‐Hydroxylase from <i>Escherichia coli</i> | 2.7 | 33 | Citations (PDF) |
| 42 | Carbon‐Nanotube‐Supported Copper Polyphthalocyanine for Efficient and Selective Electrocatalytic CO<sub>2</sub> Reduction to CO | 6.3 | 77 | Citations (PDF) |
| 43 | Mechanistic Understanding of CO<sub>2</sub> Reduction Reaction (CO2RR) Toward Multicarbon Products by Heterogeneous Copper-Based Catalysts | 12.7 | 527 | Citations (PDF) |
| 44 | High-Current-Density CO2-to-CO Electroreduction on Ag-Alloyed Zn Dendrites at Elevated Pressure | 23.4 | 139 | Citations (PDF) |
| 45 | A Heterogeneous Recyclable Rhodium‐based Catalyst for the Reduction of Pyridine Dinucleotides and Flavins | 3.6 | 8 | Citations (PDF) |
| 46 | Immobilization of a Molecular Re Complex on MOF‐derived Hierarchical Porous Carbon for CO<sub>2</sub> Electroreduction in Water/Ionic Liquid Electrolyte | 6.3 | 15 | Citations (PDF) |
| 47 | Functionalization of Carbon Nanotubes with Nickel Cyclam for the Electrochemical Reduction of CO<sub>2</sub> | 6.3 | 37 | Citations (PDF) |
| 48 | Electroreduction of CO<sub>2</sub> to Formate with Low Overpotential using Cobalt Pyridine Thiolate Complexes | 14.9 | 63 | Citations (PDF) |
| 49 | Electroreduction of CO<sub>2</sub> to Formate with Low Overpotential using Cobalt Pyridine Thiolate Complexes | 1.5 | 18 | Citations (PDF) |
| 50 | A bioinspired molybdenum–copper molecular catalyst for CO<sub>2</sub> electroreduction | 7.5 | 58 | Citations (PDF) |
| 51 | Co-immobilization of a Rh Catalyst and a Keggin Polyoxometalate in the UiO-67 Zr-Based Metal–Organic Framework: In Depth Structural Characterization and Photocatalytic Properties for CO<sub>2</sub> Reduction | 15.7 | 218 | Citations (PDF) |
| 52 | The O2-independent pathway of ubiquinone biosynthesis is essential for denitrification in Pseudomonas aeruginosa | 2.3 | 36 | Citations (PDF) |
| 53 | A Single Molecular Stoichiometric P‐Source for Phase‐Selective Synthesis of Crystalline and Amorphous Iron Phosphide Nanocatalysts | 2.5 | 9 | Citations (PDF) |
| 54 | Copper-Substituted NiTiO<sub>3</sub> Ilmenite-Type Materials for Oxygen Evolution Reaction | 8.1 | 15 | Citations (PDF) |
| 55 | Physiologically relevant reconstitution of iron-sulfur cluster biosynthesis uncovers persulfide-processing functions of ferredoxin-2 and frataxin | 14.2 | 146 | Citations (PDF) |
| 56 | Bio-inspired hydrophobicity promotes CO2 reduction on a Cu surface | 34.0 | 765 | Citations (PDF) |
| 57 | Ubiquinone Biosynthesis over the Entire O
<sub>2</sub>
Range: Characterization of a Conserved O
<sub>2</sub>
-Independent Pathway | 4.5 | 49 | Citations (PDF) |
| 58 | Electroreduction of CO<sub>2</sub> on Single‐Site Copper‐Nitrogen‐Doped Carbon Material: Selective Formation of Ethanol and Reversible Restructuration of the Metal Sites | 1.5 | 52 | Citations (PDF) |
| 59 | Electroreduction of CO<sub>2</sub> on Single‐Site Copper‐Nitrogen‐Doped Carbon Material: Selective Formation of Ethanol and Reversible Restructuration of the Metal Sites | 14.9 | 546 | Citations (PDF) |
| 60 | Shigella IpaA Binding to Talin Stimulates Filopodial Capture and Cell Adhesion | 6.2 | 23 | Citations (PDF) |
| 61 | A Soluble Metabolon Synthesizes the Isoprenoid Lipid Ubiquinone | 5.4 | 53 | Citations (PDF) |
| 62 | FeNC catalysts for CO<sub>2</sub> electroreduction to CO: effect of nanostructured carbon supports | 4.0 | 13 | Citations (PDF) |
| 63 | Controlling Hydrogen Evolution during Photoreduction of CO<sub>2</sub> to Formic Acid Using [Rh(R-bpy)(Cp*)Cl]<sup>+</sup> Catalysts: A Structure–Activity Study | 4.6 | 44 | Citations (PDF) |
| 64 | Low-cost high-efficiency system for solar-driven conversion of CO
<sub>2</sub>
to hydrocarbons | 7.5 | 155 | Citations (PDF) |
| 65 | Bioinspired Artificial [FeFe]-Hydrogenase with a Synthetic H-Cluster | 12.7 | 23 | Citations (PDF) |
| 66 | Thin Films of Fully Noble Metal-Free POM@MOF for Photocatalytic Water Oxidation | 8.1 | 77 | Citations (PDF) |
| 67 | Nickel Complexes Based on Molybdopterin-like Dithiolenes: Catalysts for CO<sub>2</sub> Electroreduction | 3.0 | 44 | Citations (PDF) |
| 68 | Zn–Cu Alloy Nanofoams as Efficient Catalysts for the Reduction of CO<sub>2</sub> to Syngas Mixtures with a Potential‐Independent H<sub>2</sub>/CO Ratio | 6.3 | 63 | Citations (PDF) |
| 69 | Spectroscopic investigations of a semi-synthetic [FeFe] hydrogenase with propane di-selenol as bridging ligand in the binuclear subsite: comparison to the wild type and propane di-thiol variants | 2.5 | 13 | Citations (PDF) |
| 70 | A Fully Noble Metal-Free Photosystem Based on Cobalt-Polyoxometalates Immobilized in a Porphyrinic Metal–Organic Framework for Water Oxidation | 15.7 | 322 | Citations (PDF) |
| 71 | A Bioinspired Nickel(bis-dithiolene) Complex as a Homogeneous Catalyst for Carbon Dioxide Electroreduction | 12.7 | 101 | Citations (PDF) |
| 72 | Engineering an [FeFe]-Hydrogenase: Do Accessory Clusters Influence O<sub>2</sub> Resistance and Catalytic Bias? | 15.7 | 64 | Citations (PDF) |
| 73 | Pyranopterin Related Dithiolene Molybdenum Complexes as Homogeneous Catalysts for CO<sub>2</sub> Photoreduction | 14.9 | 51 | Citations (PDF) |
| 74 | Pyranopterin Related Dithiolene Molybdenum Complexes as Homogeneous Catalysts for CO
2
Photoreduction | 1.5 | 8 | Citations (PDF) |
| 75 | Immobilization of a Full Photosystem in the Large‐Pore MIL‐101 Metal–Organic Framework for CO<sub>2</sub> reduction | 6.3 | 68 | Citations (PDF) |
| 76 | A Soluble Metabolon Synthesizes the Isoprenoid Lipid Ubiquinone | 0.2 | 0 | Citations (PDF) |
| 77 | Molecular polypyridine-based metal complexes as catalysts for the reduction of CO<sub>2</sub> | 38.2 | 521 | Citations (PDF) |
| 78 | Electrochemical Reduction of CO<sub>2</sub> Catalyzed by Fe-N-C Materials: A Structure–Selectivity Study | 12.7 | 418 | Citations (PDF) |
| 79 | Rhenium Complexes Based on 2-Pyridyl-1,2,3-triazole Ligands: A New Class of CO<sub>2</sub> Reduction Catalysts | 4.6 | 60 | Citations (PDF) |
| 80 | Molecular Cobalt Complexes with Pendant Amines for Selective Electrocatalytic Reduction of Carbon Dioxide to Formic Acid | 15.7 | 321 | Citations (PDF) |
| 81 | Effect of Cations on the Structure and Electrocatalytic Response of Polyoxometalate-Based Coordination Polymers | 3.5 | 57 | Citations (PDF) |
| 82 | Ruthenium–cobalt dinuclear complexes as photocatalysts for CO<sub>2</sub> reduction | 4.2 | 23 | Citations (PDF) |
| 83 | Synthesis, Characterization, and DFT Analysis of Bis-Terpyridyl-Based Molecular Cobalt Complexes | 4.6 | 70 | Citations (PDF) |
| 84 | New Cobalt‐Bisterpyridyl Catalysts for Hydrogen Evolution Reaction | 3.6 | 44 | Citations (PDF) |
| 85 | Maximizing the Photocatalytic Activity of Metal–Organic Frameworks with Aminated-Functionalized Linkers: Substoichiometric Effects in MIL-125-NH<sub>2</sub> | 15.7 | 235 | Citations (PDF) |
| 86 | Structural and functional characterization of the hydrogenase-maturation HydF protein | 12.5 | 44 | Citations (PDF) |
| 87 | The UbiK protein is an accessory factor necessary for bacterial ubiquinone (UQ) biosynthesis and forms a complex with the UQ biogenesis factor UbiJ | 2.3 | 43 | Citations (PDF) |
| 88 | A Dendritic Nanostructured Copper Oxide Electrocatalyst for the Oxygen Evolution Reaction | 14.9 | 228 | Citations (PDF) |
| 89 | A Dendritic Nanostructured Copper Oxide Electrocatalyst for the Oxygen Evolution Reaction | 1.5 | 48 | Citations (PDF) |
| 90 | The unusual ring scission of a quinoxaline-pyran-fused dithiolene system related to molybdopterin | 3.2 | 10 | Citations (PDF) |
| 91 | Site-isolated manganese carbonyl on bipyridine-functionalities of periodic mesoporous organosilicas: efficient CO<sub>2</sub> photoreduction and detection of key reaction intermediates | 7.5 | 47 | Citations (PDF) |
| 92 | Enzyme Activation with a Synthetic Catalytic Co‐enzyme Intermediate: Nucleotide Methylation by Flavoenzymes | 14.9 | 13 | Citations (PDF) |
| 93 | Nonredox thiolation in tRNA occurring via sulfur activation by a [4Fe-4S] cluster | 7.5 | 55 | Citations (PDF) |
| 94 | Porous dendritic copper: an electrocatalyst for highly selective CO<sub>2</sub> reduction to formate in water/ionic liquid electrolyte | 7.5 | 151 | Citations (PDF) |
| 95 | On the Role of Additional [4Fe-4S] Clusters with a Free Coordination Site in Radical-SAM Enzymes | 3.6 | 33 | Citations (PDF) |
| 96 | Artificial Hydrogenases Based on Cobaloximes and Heme Oxygenase | 2.7 | 31 | Citations (PDF) |
| 97 | A cobalt complex with a bioinspired molybdopterin-like ligand: a catalyst for hydrogen evolution | 3.2 | 41 | Citations (PDF) |
| 98 | Chemical assembly of multiple metal cofactors: The heterologously expressed multidomain [FeFe]-hydrogenase from Megasphaera elsdenii | 0.6 | 27 | Citations (PDF) |
| 99 | CO<sub>2</sub> Reduction to CO in Water: Carbon Nanotube–Gold Nanohybrid as a Selective and Efficient Electrocatalyst | 6.3 | 50 | Citations (PDF) |
| 100 | Cu/Cu<sub>2</sub>O Electrodes and CO<sub>2</sub> Reduction to Formic Acid: Effects of Organic Additives on Surface Morphology and Activity | 3.4 | 36 | Citations (PDF) |
| 101 | Reactivity of the Excited States of the H-Cluster of FeFe Hydrogenases | 15.7 | 26 | Citations (PDF) |
| 102 | Porous–Hybrid Polymers as Platforms for Heterogeneous Photochemical Catalysis | 8.1 | 41 | Citations (PDF) |
| 103 | Synthesis and Reactivity of a Bio‐inspired Dithiolene Ligand and its Mo Oxo Complex | 3.4 | 15 | Citations (PDF) |
| 104 | A Simple and Non‐Destructive Method for Assessing the Incorporation of Bipyridine Dicarboxylates as Linkers within Metal–Organic Frameworks | 3.4 | 28 | Citations (PDF) |
| 105 | Synthesis, electrochemical and spectroscopic properties of ruthenium(<scp>ii</scp>) complexes containing 2,6-di(1H-imidazo[4,5-f][1,10]phenanthrolin-2-yl)aryl ligands | 2.5 | 12 | Citations (PDF) |
| 106 | A Bioinspired Molybdenum Complex as a Catalyst for the Photo‐ and Electroreduction of Protons | 1.5 | 23 | Citations (PDF) |
| 107 | Electro‐Assisted Reduction of CO<sub>2</sub> to CO and Formaldehyde by (TOA)<sub>6</sub>[α‐SiW<sub>11</sub>O<sub>39</sub>Co(_)] Polyoxometalate | 1.9 | 57 | Citations (PDF) |
| 108 | A Bioinspired Molybdenum Complex as a Catalyst for the Photo‐ and Electroreduction of Protons | 14.9 | 46 | Citations (PDF) |
| 109 | Artificial hydrogenases: biohybrid and supramolecular systems for catalytic hydrogen production or uptake | 6.1 | 77 | Citations (PDF) |
| 110 | From molecular copper complexes to composite electrocatalytic materials for selective reduction of CO<sub>2</sub> to formic acid | 9.3 | 76 | Citations (PDF) |
| 111 | Artificially maturated [FeFe] hydrogenase from Chlamydomonas reinhardtii: a HYSCORE and ENDOR study of a non-natural H-cluster | 2.8 | 44 | Citations (PDF) |
| 112 | Photocatalytic Carbon Dioxide Reduction with Rhodium‐based Catalysts in Solution and Heterogenized within Metal–Organic Frameworks | 6.3 | 202 | Citations (PDF) |
| 113 | Versatile functionalization of carbon electrodes with a polypyridine ligand: metallation and electrocatalytic H<sup>+</sup> and CO<sub>2</sub> reduction | 4.2 | 78 | Citations (PDF) |
| 114 | From Enzyme Maturation to Synthetic Chemistry: The Case of Hydrogenases | 17.7 | 68 | Citations (PDF) |
| 115 | Turning it off! Disfavouring hydrogen evolution to enhance selectivity for CO production during homogeneous CO<sub>2</sub> reduction by cobalt–terpyridine complexes | 7.5 | 177 | Citations (PDF) |
| 116 | Bioinspired Tungsten Dithiolene Catalysts for Hydrogen Evolution: A Combined Electrochemical, Photochemical, and Computational Study | 2.9 | 48 | Citations (PDF) |
| 117 | Spectroscopic Characterization of the Bridging Amine in the Active Site of [FeFe] Hydrogenase Using Isotopologues of the H-Cluster | 15.7 | 73 | Citations (PDF) |
| 118 | Molecular Investigation of Iron–Sulfur Cluster Assembly Scaffolds under Stress | 2.9 | 36 | Citations (PDF) |
| 119 | TtcA a new tRNA-thioltransferase with an Fe-S cluster | 16.3 | 70 | Citations (PDF) |
| 120 | Mimicking hydrogenases: From biomimetics to artificial enzymes | 23.4 | 458 | Citations (PDF) |
| 121 | Terpyridine complexes of first row transition metals and electrochemical reduction of CO<sub>2</sub> to CO | 2.8 | 182 | Citations (PDF) |
| 122 | ubiJ, a New Gene Required for Aerobic Growth and Proliferation in Macrophage, Is Involved in Coenzyme Q Biosynthesis in Escherichia coli and Salmonella enterica Serovar Typhimurium | 3.0 | 44 | Citations (PDF) |
| 123 | An integrative computational model for large-scale identification of metalloproteins in microbial genomes: a focus on iron–sulfur cluster proteins | 2.5 | 27 | Citations (PDF) |
| 124 | Theoretical Modeling of Low‐Energy Electronic Absorption Bands in Reduced Cobaloximes | 2.0 | 14 | Citations (PDF) |
| 125 | Cobaloxime-Based Artificial Hydrogenases | 4.6 | 88 | Citations (PDF) |
| 126 | Biosynthesis and physiology of coenzyme Q in bacteria | 0.6 | 149 | Citations (PDF) |
| 127 | Engineering the Optical Response of the Titanium-MIL-125 Metal–Organic Framework through Ligand Functionalization | 15.7 | 818 | Citations (PDF) |
| 128 | Spontaneous activation of [FeFe]-hydrogenases by an inorganic [2Fe] active site mimic | 12.5 | 342 | Citations (PDF) |
| 129 | A Computational Study of the Mechanism of Hydrogen Evolution by Cobalt(Diimine‐Dioxime) Catalysts | 3.4 | 98 | Citations (PDF) |
| 130 | Activation of a Unique Flavin-Dependent tRNA-Methylating Agent | 2.9 | 27 | Citations (PDF) |
| 131 | Catalytic hydrogen production by a Ni–Ru mimic of NiFe hydrogenases involves a proton-coupled electron transfer step | 4.2 | 59 | Citations (PDF) |
| 132 | Solar fuels generation and molecular systems: is it homogeneous or heterogeneous catalysis? | 38.2 | 476 | Citations (PDF) |
| 133 | Artificial photosynthesis as a frontier technology for energy sustainability | 30.6 | 304 | Citations (PDF) |
| 134 | <i>In vivo</i> [<scp>F</scp>e‐<scp>S</scp>] cluster acquisition by <scp>IscR</scp> and <scp>NsrR</scp>, two stress regulators in <i><scp>E</scp>scherichia coli</i> | 2.7 | 49 | Citations (PDF) |
| 135 | Two Fe-S clusters catalyze sulfur insertion by radical-SAM methylthiotransferases | 12.5 | 123 | Citations (PDF) |
| 136 | Biomimetic assembly and activation of [FeFe]-hydrogenases | 34.3 | 666 | Citations (PDF) |
| 137 | Dye-sensitized nanostructured crystalline mesoporous tin-doped indium oxide films with tunable thickness for photoelectrochemical applications | 9.3 | 33 | Citations (PDF) |
| 138 | ubiI, a New Gene in Escherichia coli Coenzyme Q Biosynthesis, Is Involved in Aerobic C5-hydroxylation | 2.3 | 52 | Citations (PDF) |
| 139 | An EPR/HYSCORE, Mössbauer, and resonance Raman study of the hydrogenase maturation enzyme HydF: a model for N-coordination to [4Fe–4S] clusters | 2.5 | 28 | Citations (PDF) |
| 140 | 4-Demethylwyosine Synthase from Pyrococcus abyssi Is a Radical-S-adenosyl-l-methionine Enzyme with an Additional [4Fe-4S]+2 Cluster That Interacts with the Pyruvate Co-substrate | 2.3 | 45 | Citations (PDF) |
| 141 | Flavin Conjugates for Delivery of Peptide Nucleic Acids | 2.7 | 11 | Citations (PDF) |
| 142 | FAD/Folate-Dependent tRNA Methyltransferase: Flavin as a New Methyl-Transfer Agent | 15.7 | 43 | Citations (PDF) |
| 143 | Molecular organization, biochemical function, cellular role and evolution of NfuA, an atypical Fe‐S carrier | 2.7 | 89 | Citations (PDF) |
| 144 | Mesoporous α-Fe2O3 thin films synthesized via the sol–gel process for light-driven water oxidation | 2.8 | 60 | Citations (PDF) |
| 145 | A Janus cobalt-based catalytic material for electro-splitting of water | 34.0 | 834 | Citations (PDF) |
| 146 | The methylthiolation reaction mediated by the Radical-SAM enzymes | 2.0 | 27 | Citations (PDF) |
| 147 | Phosphine Coordination to a Cobalt Diimine–Dioxime Catalyst Increases Stability during Light-Driven H<sub>2</sub> Production | 4.6 | 102 | Citations (PDF) |
| 148 | Combined Experimental–Theoretical Characterization of the Hydrido-Cobaloxime [HCo(dmgH)<sub>2</sub>(P<i>n</i>Bu<sub>3</sub>)] | 4.6 | 61 | Citations (PDF) |
| 149 | Molecular engineering of a cobalt-based electrocatalytic nanomaterial for H2 evolution under fully aqueous conditions | 18.5 | 382 | Citations (PDF) |
| 150 | Cobalt stress in Escherichia coli and Salmonella enterica: molecular bases for toxicity and resistance | 2.5 | 99 | Citations (PDF) |
| 151 | Artificial Photosynthesis: From Molecular Catalysts for Light‐driven Water Splitting to Photoelectrochemical Cells | 2.9 | 289 | Citations (PDF) |
| 152 | Light-driven bioinspired water splitting: Recent developments in photoelectrode materials | 0.7 | 23 | Citations (PDF) |
| 153 | Bioinspired catalysis at the crossroads between biology and chemistry: A remarkable example of an electrocatalytic material mimicking hydrogenases | 0.7 | 33 | Citations (PDF) |
| 154 | Cp*<sup>–</sup>‐Ruthenium–Nickel‐Based H<sub>2</sub>‐Evolving Electrocatalysts as Bio‐inspired Models of NiFe Hydrogenases | 1.9 | 30 | Citations (PDF) |
| 155 | Further Characterization of the [FeFe]‐Hydrogenase Maturase HydG | 1.9 | 22 | Citations (PDF) |
| 156 | Noncovalent Modification of Carbon Nanotubes with Pyrene‐Functionalized Nickel Complexes: Carbon Monoxide Tolerant Catalysts for Hydrogen Evolution and Uptake | 1.5 | 74 | Citations (PDF) |
| 157 | Wasserspaltung mit Cobalt | 1.5 | 201 | Citations (PDF) |
| 158 | Noncovalent Modification of Carbon Nanotubes with Pyrene‐Functionalized Nickel Complexes: Carbon Monoxide Tolerant Catalysts for Hydrogen Evolution and Uptake | 14.9 | 276 | Citations (PDF) |
| 159 | Splitting Water with Cobalt | 14.9 | 1,344 | Citations (PDF) |
| 160 | Methylations: A Radical Mechanism | 6.1 | 1 | Citations (PDF) |
| 161 | Water electrolysis and photoelectrolysis on electrodes engineered using biological and bio-inspired molecular systems | 30.6 | 197 | Citations (PDF) |
| 162 | Mechanism of hydrogen evolution catalyzed by NiFe hydrogenases: insights from a Ni–Ru model compound | 3.2 | 42 | Citations (PDF) |
| 163 | S-Adenosylmethionine-dependent radical-based modification of biological macromolecules | 7.1 | 53 | Citations (PDF) |
| 164 | Das Leben molekular verstehen: Reduktionismus gegen Vitalismus | 1.5 | 1 | Citations (PDF) |
| 165 | Understanding Life as Molecules: Reductionism Versus Vitalism | 14.9 | 17 | Citations (PDF) |
| 166 | Maturation of [FeFe]-hydrogenases: Structures and mechanisms | 9.2 | 25 | Citations (PDF) |
| 167 | Biohydrogen: From Basic Concepts to Technology | 9.2 | 1 | Citations (PDF) |
| 168 | A genetic analysis of the response of <i>Escherichia coli</i> to cobalt stress | 3.7 | 68 | Citations (PDF) |
| 169 | Identification of Eukaryotic and Prokaryotic Methylthiotransferase for Biosynthesis of 2-Methylthio-N6-threonylcarbamoyladenosine in tRNA | 2.3 | 121 | Citations (PDF) |
| 170 | Iron-Sulfur (Fe-S) Cluster Assembly | 2.3 | 133 | Citations (PDF) |
| 171 | Post-translational Modification of Ribosomal Proteins | 2.3 | 61 | Citations (PDF) |
| 172 | H<sub>2</sub> Evolution and Molecular Electrocatalysts: Determination of Overpotentials and Effect of Homoconjugation | 4.6 | 458 | Citations (PDF) |
| 173 | A structural and functional mimic of the active site of NiFe hydrogenases | 4.2 | 104 | Citations (PDF) |
| 174 | Iron–Sulfur Clusters in “Radical SAM” Enzymes: Spectroscopy and Coordination | 0.0 | 1 | Citations (PDF) |
| 175 | Native Escherichia coli SufA, Coexpressed with SufBCDSE, Purifies as a [2Fe−2S] Protein and Acts as an Fe−S Transporter to Fe−S Target Enzymes | 15.7 | 92 | Citations (PDF) |
| 176 | The role of the maturase HydG in [FeFe]‐hydrogenase active site synthesis and assembly | 2.8 | 137 | Citations (PDF) |
| 177 | Cyclopentadienyl Ruthenium–Nickel Catalysts for Biomimetic Hydrogen Evolution: Electrocatalytic Properties and Mechanistic DFT Studies | 3.4 | 62 | Citations (PDF) |
| 178 | The Zn center of the anaerobic ribonucleotide reductase from E. coli | 2.5 | 16 | Citations (PDF) |
| 179 | The CsdA cysteine desulphurase promotes Fe/S biogenesis by recruiting Suf components and participates to a new sulphur transfer pathway by recruiting CsdL (ex‐YgdL), a ubiquitin‐modifying‐like protein | 2.7 | 56 | Citations (PDF) |
| 180 | Synthesis, crystal structure, magnetic properties and reactivity of a Ni–Ru model of NiFe hydrogenases with a pentacoordinated triplet (S=1) NiII center | 2.1 | 35 | Citations (PDF) |
| 181 | Cobalt and nickel diimine-dioxime complexes as molecular electrocatalysts for hydrogen evolution with low overvoltages | 7.5 | 423 | Citations (PDF) |
| 182 | Cobaloxime‐Based Photocatalytic Devices for Hydrogen Production | 14.9 | 413 | Citations (PDF) |
| 183 | Cobaloxime‐Based Photocatalytic Devices for Hydrogen Production | 1.5 | 105 | Citations (PDF) |
| 184 | New Light on Methylthiolation Reactions | 6.1 | 5 | Citations (PDF) |
| 185 | Modelling NiFe hydrogenases: nickel-based electrocatalysts for hydrogen production | 3.2 | 146 | Citations (PDF) |
| 186 | The [4Fe–4S] cluster of quinolinate synthase from <i>Escherichia coli</i>: Investigation of cluster ligands | 2.8 | 26 | Citations (PDF) |
| 187 | Iron–sulfur cluster biosynthesis in bacteria: Mechanisms of cluster assembly and transfer | 2.8 | 174 | Citations (PDF) |
| 188 | Efficient H2-producing photocatalytic systems based on cyclometalated iridium- and tricarbonylrhenium-diimine photosensitizers and cobaloxime catalysts | 3.2 | 237 | Citations (PDF) |
| 189 | DNA Repair and Free Radicals, New Insights into the Mechanism of Spore Photoproduct Lyase Revealed by Single Amino Acid Substitution | 2.3 | 65 | Citations (PDF) |
| 190 | X-ray Structure of the [FeFe]-Hydrogenase Maturase HydE from Thermotoga maritima | 2.3 | 119 | Citations (PDF) |
| 191 | NfuA, a New Factor Required for Maturing Fe/S Proteins in Escherichia coli under Oxidative Stress and Iron Starvation Conditions | 2.3 | 141 | Citations (PDF) |
| 192 | From Iron and Cysteine to Iron-Sulfur Clusters: the Biogenesis Protein Machineries | 4.0 | 17 | Citations (PDF) |
| 193 | Cobalt Stress in Escherichia coli | 2.3 | 176 | Citations (PDF) |
| 194 | Characterization of Arabidopsis thaliana SufE2 and SufE3 | 2.3 | 93 | Citations (PDF) |
| 195 | tRNA-modifying MiaE protein from<i>Salmonella typhimurium</i>is a nonheme diiron monooxygenase | 7.5 | 45 | Citations (PDF) |
| 196 | SufE Transfers Sulfur from SufS to SufB for Iron-Sulfur Cluster Assembly | 2.3 | 153 | Citations (PDF) |
| 197 | ErpA, an iron–sulfur (Fe–S) protein of the A-type essential for respiratory metabolism in
<i>Escherichia coli</i> | 7.5 | 143 | Citations (PDF) |
| 198 | The SUF iron-sulfur cluster biosynthetic machinery: Sulfur transfer from the SUFS-SUFE complex to SUFA | 2.8 | 42 | Citations (PDF) |
| 199 | Cobaloximes as Functional Models for Hydrogenases. 2. Proton Electroreduction Catalyzed by Difluoroborylbis(dimethylglyoximato)cobalt(II) Complexes in Organic Media | 4.6 | 376 | Citations (PDF) |
| 200 | MiaB, a Bifunctional Radical-S-Adenosylmethionine Enzyme Involved in the Thiolation and Methylation of tRNA, Contains Two Essential [4Fe-4S] Clusters | 2.9 | 119 | Citations (PDF) |
| 201 | Chiral-at-Metal Ruthenium Complex as a Metalloligand for Asymmetric Catalysis | 4.6 | 52 | Citations (PDF) |
| 202 | Dinuclear Nickel–Ruthenium Complexes as Functional Bio-Inspired Models of [NiFe] Hydrogenases | 1.9 | 62 | Citations (PDF) |
| 203 | Characterization of the DNA repair spore photoproduct lyase enzyme from Clostridium acetobutylicum: A radical-SAM enzyme | 0.7 | 13 | Citations (PDF) |
| 204 | The spore photoproduct lyase repairs the 5S- and not the 5R-configured spore photoproduct DNA lesion | 4.2 | 41 | Citations (PDF) |
| 205 | [Ni(xbsms)Ru(CO)2Cl2]: A Bioinspired Nickel−Ruthenium Functional Model of [NiFe] Hydrogenase | 4.6 | 69 | Citations (PDF) |
| 206 | Iron-sulfur clusters: ever-expanding roles | 12.5 | 216 | Citations (PDF) |
| 207 | Sequence-Specific Nucleic Acid Damage Induced by Peptide Nucleic Acid Conjugates That Can Be Enzyme-Activated | 14.9 | 5 | Citations (PDF) |
| 208 | Sequence-Specific Nucleic Acid Damage Induced by Peptide Nucleic Acid Conjugates That Can Be Enzyme-Activated | 1.5 | 1 | Citations (PDF) |
| 209 | Iron-Sulfur Cluster Biosynthesis | 2.3 | 165 | Citations (PDF) |
| 210 | The [Fe-Fe]-Hydrogenase Maturation Protein HydF from Thermotoga maritima Is a GTPase with an Iron-Sulfur Cluster | 2.3 | 125 | Citations (PDF) |
| 211 | Dinucleotide Spore Photoproduct, a Minimal Substrate of the DNA Repair Spore Photoproduct Lyase Enzyme from Bacillus subtilis | 2.3 | 53 | Citations (PDF) |
| 212 | Some general principles for designing electrocatalysts with hydrogenase activity | 23.4 | 330 | Citations (PDF) |
| 213 | Chiral-at-Metal Complexes as Asymmetric Catalysts 2005, , 271-288 | | 98 | Citations (PDF) |
| 214 | DNA Detection through Signal Amplification by Using NADH:Flavin Oxidoreductase and Oligonucleotide-Flavin Conjugates as Cofactors | 14.9 | 31 | Citations (PDF) |
| 215 | DNA Detection through Signal Amplification by Using NADH:Flavin Oxidoreductase and Oligonucleotide-Flavin Conjugates as Cofactors | 1.5 | 14 | Citations (PDF) |
| 216 | Activation of the Anaerobic Ribonucleotide Reductase by S-Adenosylmethionine | 2.7 | 28 | Citations (PDF) |
| 217 | Mechanisms of iron–sulfur cluster assembly: the SUF machinery | 2.5 | 106 | Citations (PDF) |
| 218 | Analysis of the Heteromeric CsdA-CsdE Cysteine Desulfurase, Assisting Fe-S Cluster Biogenesis in Escherichia coli | 2.3 | 104 | Citations (PDF) |
| 219 | Proton Electroreduction Catalyzed by Cobaloximes: Functional Models for Hydrogenases | 4.6 | 424 | Citations (PDF) |
| 220 | The flavin reductase ActVB fromStreptomyces coelicolor: Characterization of the electron transferase activity of the flavoprotein form | 2.8 | 15 | Citations (PDF) |
| 221 | Quinolinate synthetase, an iron-sulfur enzyme in NAD biosynthesis | 2.8 | 92 | Citations (PDF) |
| 222 | Biochemical characterization of the HydE and HydG iron-only hydrogenase maturation enzymes fromThermatoga maritima | 2.8 | 143 | Citations (PDF) |
| 223 | MiaB Protein Is a Bifunctional Radical-S-Adenosylmethionine Enzyme Involved in Thiolation and Methylation of tRNA | 2.3 | 157 | Citations (PDF) |
| 224 | S-adenosylmethionine: nothing goes to waste | 6.7 | 553 | Citations (PDF) |
| 225 | SufA/IscA: reactivity studies of a class of scaffold proteins involved in [Fe-S] cluster assembly | 2.5 | 86 | Citations (PDF) |
| 226 | Crystallization-Induced Asymmetric Transformation of Chiral-at-metal Ruthenium(II) Complexes Bearing Achiral Ligands | 3.4 | 35 | Citations (PDF) |
| 227 | New flavin and deazaflavin oligonucleotide conjugates for the amperometric detection of DNA hybridization | 4.2 | 6 | Citations (PDF) |
| 228 | Biological Radical Sulfur Insertion Reactions | 54.7 | 195 | Citations (PDF) |
| 229 | Mechanistic studies of the SufS-SufE cysteine desulfurase: evidence for sulfur transfer from SufS to SufE | 2.8 | 98 | Citations (PDF) |
| 230 | SufA from Erwinia chrysanthemi | 2.3 | 87 | Citations (PDF) |
| 231 | MiaB Protein from Thermotoga maritima | 2.3 | 60 | Citations (PDF) |
| 232 | Biogenesis of Fe-S Cluster by the Bacterial Suf System | 2.3 | 211 | Citations (PDF) |
| 233 | A metal-binding site in the catalytic subunit of anaerobic ribonucleotide reductase | 7.5 | 33 | Citations (PDF) |
| 234 | Reductive Cleavage of S-Adenosylmethionine by Biotin Synthase from Escherichia coli | 2.3 | 62 | Citations (PDF) |
| 235 | Deoxyribonucleotide synthesis in anaerobic microorganisms: The class III ribonucleotide reductase | 0.0 | 50 | Citations (PDF) |
| 236 | Enzymatic Modification of tRNAs | 2.3 | 102 | Citations (PDF) |
| 237 | Biotin Synthase Is a Pyridoxal Phosphate-Dependent Cysteine Desulfurase | 2.9 | 53 | Citations (PDF) |
| 238 | The PLP-dependent biotin synthase from Escherichia coli
: mechanistic studies | 2.8 | 39 | Citations (PDF) |
| 239 | Fluorescent Deazaflavin-Oligonucleotide Probes for Selective Detection of DNA | 1.5 | 8 | Citations (PDF) |
| 240 | A Diferric Peroxo Complex with an Unprecedented Spin Configuration: AnS=2 System Arising from anS=5/2, 1/2 Pair | 1.5 | 1 | Citations (PDF) |
| 241 | Fluorescent Deazaflavin-Oligonucleotide Probes for Selective Detection of DNA | 14.9 | 24 | Citations (PDF) |
| 242 | A Diferric Peroxo Complex with an Unprecedented Spin Configuration: AnS=2 System Arising from anS=5/2, 1/2 Pair | 14.9 | 24 | Citations (PDF) |
| 243 | Title is missing! | 3.3 | 140 | Citations (PDF) |
| 244 | Activation of Class III Ribonucleotide Reductase fromE. coli. The Electron Transfer from the Iron−Sulfur Center toS-Adenosylmethionine† | 2.9 | 48 | Citations (PDF) |
| 245 | Activation of Class III Ribonucleotide Reductase by Flavodoxin: A Protein Radical-Driven Electron Transfer to the Iron−Sulfur Center | 2.9 | 47 | Citations (PDF) |
| 246 | Adenosylmethionine as a source of 5′-deoxyadenosyl radicals | 6.1 | 88 | Citations (PDF) |
| 247 | Mechanisms of formation of free radicals in biological catalysis | 0.1 | 9 | Citations (PDF) |
| 248 | Activation of Class III Ribonucleotide Reductase by Thioredoxin | 2.3 | 25 | Citations (PDF) |
| 249 | Iron-Sulfur Cluster Assembly | 2.3 | 183 | Citations (PDF) |
| 250 | The iron-sulfur center of biotin synthase: site-directed mutants | 2.5 | 47 | Citations (PDF) |
| 251 | The Activating Component of the Anaerobic Ribonucleotide Reductase from Escherichia coli | 2.3 | 58 | Citations (PDF) |
| 252 | Iron-Sulfur Center of Biotin Synthase and Lipoate Synthase | 2.9 | 107 | Citations (PDF) |
| 253 | The NAD(P)H:Flavin Oxidoreductase from Escherichia coli | 2.3 | 39 | Citations (PDF) |
| 254 | The Anaerobic Ribonucleotide Reductase from Escherichia coli | 2.3 | 58 | Citations (PDF) |
| 255 | Title is missing! 1999, 12, 195-199 | | 238 | Citations (PDF) |
| 256 | Iron-sulfur interconversions in the anaerobic ribonucleotide reductase from Escherichia coli | 2.5 | 24 | Citations (PDF) |
| 257 | Enantioselective Sulfoxidation as a Probe for a Metal-Based Mechanism in H2O2-Dependent Oxidations Catalyzed by a Diiron Complex | 4.6 | 77 | Citations (PDF) |
| 258 | The lipoate synthase from Escherichia coli
is an iron-sulfur protein | 2.8 | 59 | Citations (PDF) |
| 259 | Assembly of 2Fe-2S and 4Fe-4S Clusters in the Anaerobic Ribonucleotide Reductase from Escherichia coli | 15.7 | 63 | Citations (PDF) |
| 260 | Crystal Structure of NAD(P)H:Flavin Oxidoreductase from Escherichia coli, | 2.9 | 89 | Citations (PDF) |
| 261 | Flavin-oligonucleotide conjugates: sequence specific photocleavage of DNA | 4.2 | 12 | Citations (PDF) |
| 262 | Reaction of the NAD(P)H:Flavin Oxidoreductase fromEscherichia coliwith NADPH and Riboflavin: Identification of Intermediates† | 2.9 | 30 | Citations (PDF) |
| 263 | Activation of the Anaerobic Ribonucleotide Reductase fromEscherichia coli | 2.3 | 142 | Citations (PDF) |
| 264 | Method for Preparing New Flavin Derivatives: Synthesis of Flavin−Thymine Nucleotides and Flavin−Oligonucleotide Adducts | 3.8 | 27 | Citations (PDF) |
| 265 | Is the NAD(P)H:Flavin Oxidoreductase from a Member of the Ferredoxin-NADP+ Reductase Family? | 2.3 | 35 | Citations (PDF) |
| 266 | The Anaerobic Escherichia coli Ribonucleotide Reductase | 2.3 | 83 | Citations (PDF) |
| 267 | The Free Radical of the Anaerobic Ribonucleotide Reductase from Escherichia coli Is at Glycine 681 | 2.3 | 141 | Citations (PDF) |
| 268 | Formate is the hydrogen donor for the anaerobic ribonucleotide reductase from Escherichia coli. | 7.5 | 95 | Citations (PDF) |
| 269 | The Mechanism and Substrate Specificity of the NADPH:Flavin Oxidoreductase from Escherichia coli | 2.3 | 117 | Citations (PDF) |
| 270 | Ferric reductases or flavin reductases? | 3.3 | 103 | Citations (PDF) |
| 271 | The NAD(P)H:flavin oxidoreductase from Escherichia coli as a source of superoxide radicals. | 2.3 | 71 | Citations (PDF) |
| 272 | The anaerobic ribonucleoside triphosphate reductase from Escherichia coli requires S-adenosylmethionine as a cofactor. | 7.5 | 84 | Citations (PDF) |
| 273 | NAD(P)H:flavin oxidoreductase of Escherichia coli. A ferric iron reductase participating in the generation of the free radical of ribonucleotide reductase. | 2.3 | 176 | Citations (PDF) |
| 274 | Controlled Growth of a Photocatalytic Metal–Organic Framework on Conductive Plates by Mixing Direct Synthesis and Postsynthetic Modification Strategies | 5.4 | 3 | Citations (PDF) |
| 275 | Silver and Copper Nitride Cooperate for CO Electroreduction to Propanol | 1.5 | 1 | Citations (PDF) |
| 276 | Light-Activated Artificial CO<sub>2</sub>-Reductase: Structure and Activity | 15.7 | 1 | Citations (PDF) |
