| Improved water electrolysis using magnetic heating of FeC–Ni core–shell nanoparticles C Niether, S Faure, A Bordet, J Deseure, M Chatenet, J Carrey, ... Nature Energy 3 (6), 476-483, 2018 | 325 | 2018 |
| Magnetically Induced Continuous CO2 Hydrogenation Using Composite Iron Carbide Nanoparticles of Exceptionally High Heating Power A Bordet, LM Lacroix, PF Fazzini, J Carrey, K Soulantica, B Chaudret Angewandte Chemie International Edition 55 (51), 15894-15898, 2016 | 160 | 2016 |
| Bimetallic nanoparticles in supported ionic liquid phases as multifunctional catalysts for the selective hydrodeoxygenation of aromatic substrates L Offner‐Marko, A Bordet, G Moos, S Tricard, S Rengshausen, ... Angewandte Chemie 130 (39), 12903-12908, 2018 | 66 | 2018 |
| Enhancing the catalytic properties of ruthenium nanoparticle-SILP catalysts by dilution with iron KL Luska, A Bordet, S Tricard, I Sinev, W Grünert, B Chaudret, W Leitner ACS Catalysis 6 (6), 3719-3726, 2016 | 64 | 2016 |
| Selective hydrogenation and hydrodeoxygenation of aromatic ketones to cyclohexane derivatives using a Rh@ SILP catalyst G Moos, M Emondts, A Bordet, W Leitner Angewandte Chemie International Edition 59 (29), 11977-11983, 2020 | 57 | 2020 |
| Selective hydrogenation of benzofurans using ruthenium nanoparticles in Lewis acid-modified ruthenium-supported ionic liquid phases S El Sayed, A Bordet, C Weidenthaler, W Hetaba, KL Luska, W Leitner ACS Catalysis 10 (3), 2124-2130, 2020 | 50 | 2020 |
| Metal nanoparticles immobilized on molecularly modified surfaces: versatile catalytic systems for controlled hydrogenation and hydrogenolysis A Bordet, W Leitner Accounts of Chemical Research 54 (9), 2144-2157, 2021 | 48 | 2021 |
| Water-dispersible and biocompatible iron carbide nanoparticles with high specific absorption rate A Bordet, RF Landis, YW Lee, GY Tonga, JM Asensio, CH Li, PF Fazzini, ... ACS nano 13 (3), 2870-2878, 2019 | 48 | 2019 |
| Iron carbide or iron carbide/cobalt nanoparticles for magnetically-induced CO 2 hydrogenation over Ni/SiRAlOx catalysts SS Kale, JM Asensio, M Estrader, M Werner, A Bordet, D Yi, J Marbaix, ... Catalysis Science & Technology 9 (10), 2601-2607, 2019 | 35 | 2019 |
| Selectivity control in hydrogenation through adaptive catalysis using ruthenium nanoparticles on a CO2-responsive support A Bordet, S El Sayed, M Sanger, KJ Boniface, D Kalsi, KL Luska, ... Nature Chemistry 13 (9), 916-922, 2021 | 32 | 2021 |
| One-pot dual catalysis for the hydrogenation of heteroarenes and arenes B Chatterjee, D Kalsi, A Kaithal, A Bordet, W Leitner, C Gunanathan Catalysis Science & Technology 10 (15), 5163-5170, 2020 | 32 | 2020 |
| Molecular control of the catalytic properties of rhodium nanoparticles in supported ionic liquid phase (SILP) systems A Bordet, G Moos, C Welsh, P Licence, KL Luska, W Leitner ACS catalysis 10 (23), 13904-13912, 2020 | 27 | 2020 |
| Organometallic Synthesis of Bimetallic Cobalt‐Rhodium Nanoparticles in Supported Ionic Liquid Phases (CoxRh100−x@SILP) as Catalysts for the Selective … S Rengshausen, C Van Stappen, N Levin, S Tricard, KL Luska, S DeBeer, ... Small 17 (5), 2006683, 2021 | 26 | 2021 |
| Effect of Ligand Electronics on the Reversible Catalytic Hydrogenation of CO2 to Formic Acid Using Ruthenium Polyhydride Complexes: A Thermodynamic and … DP Estes, M Leutzsch, L Schubert, A Bordet, W Leitner ACS Catalysis 10 (5), 2990-2998, 2020 | 25 | 2020 |
| A new approach to the mechanism of Fischer–Tropsch syntheses arising from gas phase NMR and mass spectrometry A Bordet, LM Lacroix, K Soulantica, B Chaudret ChemCatChem 8 (9), 1727-1731, 2016 | 25 | 2016 |
| Catalytic hydrogenolysis of substituted diaryl ethers by using ruthenium nanoparticles on an acidic supported ionic liquid phase (Ru@ SILP-SO3H) S Rengshausen, F Etscheidt, J Großkurth, KL Luska, A Bordet, W Leitner Synlett 30 (04), 405-412, 2019 | 22 | 2019 |
| Selective hydrodeoxygenation of hydroxyacetophenones to ethyl-substituted phenol derivatives using a FeRu@ SILP catalyst L Goclik, L Offner-Marko, A Bordet, W Leitner Chemical Communications 56 (66), 9509-9512, 2020 | 21 | 2020 |
| Commercial Cu2Cr2O5 Decorated with Iron Carbide Nanoparticles as a Multifunctional Catalyst for Magnetically Induced Continuous‐Flow Hydrogenation of … H Kreissl, J Jin, SH Lin, D Schüette, S Störtte, N Levin, B Chaudret, ... Angewandte Chemie International Edition 60 (51), 26639-26646, 2021 | 20 | 2021 |
| Electrocatalytic hydrogenation of alkenes with Pd/carbon nanotubes at an oil–water interface C Han, J Zenner, J Johny, N Kaeffer, A Bordet, W Leitner Nature Catalysis 5 (12), 1110-1119, 2022 | 19 | 2022 |
| Enhancement of Carbon Oxides Hydrogenation on Iron‐Based Nanoparticles by In‐Situ Water Removal A Bordet, JM Asensio, K Soulantica, B Chaudret ChemCatChem 10 (18), 4047-4051, 2018 | 18 | 2018 |
