|
Year | Catalysts | Method of catalysts synthesis | Application | Ref. |
|
2019 | Mn catalysts on various supports | Coprecipitation | Carbon monoxide oxidation | [50] |
Copper promoted ceria | Hydrothermal | Carbon monoxide oxidation | [51] |
Copper on titania aerogel | Wet impregnation | Carbon monoxide oxidation | [52] |
Pd supported on CeO2(100) and CeO2(111) facets | Hydrothermal | Carbon monoxide oxidation | [53] |
Copper on titania hollow sphere | Wet chemical | Methanol oxidation | [54] |
Pt-based catalysts | Chemical reduction | Glycerol | [55] |
RuO2/TiO2 catalyst | — | Hg° oxidation | [56] |
MnO2 hollow sphere | Precipitation | Formaldehyde oxidation | [57] |
|
2018 | Ruthenium catalyst | — | Water oxidation | [58] |
Solid catalyst on various supports | Impregnation | 1-Octonol oxidation | [59] |
Bioinspired manganese catalysts | — | Enantioselective oxidation of spirocyclic compounds | [60] |
Pt catalyst on carbon | — | Xylose | [61] |
α-ZrP. Mn(II) | Ion exchange | Cyclohexane oxidation | [62] |
|
2017 | Pt-Sn on carbon support | Formic acid reduction | Ethanol and carbon monoxide oxidation | [63] |
Pt-Ru/C | Colloidal method | Glycerol oxidation | [64] |
Porphyrinic metal-organic framework | Postsynthetic modification | Cyclohexane | [65] |
MnOx-CeO2 supported on Co-N-C | Coprecipitation | Ethylbenzene oxidation | [66] |
|
2016 | Pd-Pt nanocubes | Wet impregnation | Carbon monoxide oxidation | [67] |
Pt3Ni alloy nanoparticles | Impregnation | Carbon monoxide oxidation | [68] |
Boron-doped crystalline diamond | — | Aliphatic polyamine oxidation | [69] |
Pd/graphene | Sonoelectrochemical and chemical-reduction | Glucose oxidation | [70] |
PdO/graphene | Cyclic voltammetry (CV) and chronoamperometry (CA) | Ethanol oxidation | [71] |
Graphene-supported palladium | — | Formaldehyde oxidation | [72] |
|
2015 | PtAg bimetallic alloy | Coreduction | Methanol oxidation | [73] |
Pt/carbon xerogel and Vulcan carbon | Impregnation, microemulsion | Methanol oxidation | [74] |
Nickel supported on nitrogen-doped carbon nanotubes | Hydrothermal | Hydrogen oxidation | [27] |
Lanthanum-based perovskite supports for AuPt nanoparticles | SAS precipitation | Glycerol oxidation | [75] |
|
2014 | Au/MnO | Photochemical, electrochemical | Water oxidation | [76] |
Pd-Cu nanoalloy | Soft chemical method | Methanol oxidation | [77] |
Cu (II) functionalized Fe3O4 | — | Sulfides and thiols | [78] |
Pd-Cu bimetal | Coreduction | Ethanol oxidation | [79] |
Pd nanohollow/Pt nanorod core/shell composite | Multistep crystalline growth | Methanol oxidation | [80] |
|
2013 | Au/Mg(OH)2 | Deposition | Carbon monoxide | [81] |
Au/Al2O3, Au/C | Dispersion | Glucose oxidation | [82] |
Au/Pt bimetallic nanoparticles | Dispersion, reduction | Glucose oxidation | [83] |
Au/CuO | Coprecipitation | Carbon monoxide | [84] |
|
2012 | Au/C | Incipient wet impregnation | Glucose oxidation | [85] |
Au/SiO2 | Stöber method | Cyclohexene and d-glucose oxidation | [86] |
Au-Cu/SiO2 | Two-step method | Alcohol | [87] |
Au-Pd/MgO | Sol immobilization, adsorption-reduction | Benzyl alcohol oxidation | [88] |
|
2011 | Pd-Ni electrocatalysts | Nanocapsule | Ethanol oxidation | [89] |
|
2010 | PtBi/C electrocatalysts | Borohydride reduction | Ethanol electrooxidation | [90] |
PdIr/C | Simultaneous reduction | Ethanol oxidation | [91] |
PtSn/C-Rh, PtSn/C-CeO | Alcohol reduction, polymeric precursor | Ethanol oxidation | [92] |
|
2009 | Gold nanoparticles | Reduction | Glucose and 1-phenyl ethanol | [93] |
Supported gold nanoparticles | — | Silanol oxidation | [94] |
|
2008 | Metalloporphyrin and cobalt acetate | Condensation | p-Xylene oxidation | [95] |
Au/TiO2 | Deposition precipitation | Alcohol oxidation | [96] |
|
2007 | Gold catalysts | — | Alcohol oxidation | [97] |
CuO/mesoporous silica | Impregnation | Benzene oxidation | [98] |
Supported gold catalysts | Deposition precipitation | Alcohol oxidation | [99] |
|
2005 | Gold with anionic ligand | Precipitation | Alcohol oxidation | [100] |
|