TODARO, SERENA
TODARO, SERENA
Istituto di Tecnologie Avanzate per l'Energia - ITAE
Metal-oxide interfaces and oxygen vacancies as dominant active sites in CO2 hydrogenation to methanol: Contrasting reactivity of Cu- and In-based functionalities
2026 Todaro, S.; Arena, F.; Cannilla, C.; Corrente, C.; Cajumi, A.; Samperi, M.; Santoro, M.; Frusteri, F.; Bonura, G.
3D printed CuZnAl2O3-based catalysts for direct CO2 hydrogenation to DME, optimization and scale up
2024 De Vos, Yoran; Koekkoek, Arie J. J.; Bonura, Giuseppe; Todaro, Serena; Kus, Monika; Vansant, Alexander; Gerritsen, Gijsbert; Cannilla, Catia; Abbenhuis, Hendrikus C. L.; Middelkoop, Vesna
CO-PROX on MnO2 catalysts: DFT-based microkinetic and experimental macrokinetic approaches
2024 Gueci, L.; Arena, F.; Todaro, S.; Bonura, G.; Cajumi, A.; Bertini, M.; Ferrante, F.; Nania, C.; Duca, D.
Kinetic Modeling of the Direct Dimethyl Ether (DME) Synthesis over Hybrid Multi-Site Catalysts
2024 D'Ambrosio, A.; Bertino, A.; Todaro, S.; Santoro, M.; Cannilla, C.; Frusteri, F.; Bonura, G.; Mazzeo, L.; Piemonte, V.
Molecular dynamics and kinetic modelling of the CO and H2 oxidation pattern of a composite MnCeOx catalyst
2024 Arena, Francesco; Ferrante, Francesco; Cajumi, Alessandro; Cannilla, Catia; Todaro, Serena; Bertini, Marco; Gueci, Laura; Bonura, Giuseppe; Pászti, Zoltán; Duca, Dario
Unravelling the Influence of Binder Typology during the Additive Manufacturing of Hybrid Multi-Channel Cylinders for Catalytic Purposes
2024 Todaro, S.; Bonura, G.; Cajumi, A.; Santoro, M.; Randazzo, F.; Giacoppo, G.; Frusteri, F.; Cannilla, C.
Effectiveness of the 3D-printing procedure in the synthesis of hybrid catalysts for the direct hydrogenation of CO2 into dimethyl ether
2023 Bonura, G; Todaro, S; Middelkoop, V; de Vos, Y; Abbenhuis, Hcl; Gerritsen, G; Koekkoek, Ajj; Cannilla, C; Frusteri, F
Optimizing barium promoter for nickel catalyst supported on yttria-stabilized zirconia in dry reforming of methane
2023 Al-Fatesh, A. S.; A, Ibrahim; Osman, A. I.; F, Albaqi; R, Arasheed; Frusteri, F.; Todaro, S.; K, Anojaidi; Lanre, M. S.; Abasaeed, A. E.; Fakeeha, A. H.; A, Bentalib; A., Bagabas
Copper and Iron Cooperation on Micro-Spherical Silica during Methanol Synthesis via CO2 Hydrogenation
2022 Todaro, S; Frusteri, F; Wawrzynczak, D; Majchrzakkuceba, I; Perezrobles, Jf; Cannilla, C; Bonura, G
Membrane-assisted reactor for the direct conversion of CO2 to DME/MeOH
2022 Frusteri, Francesco; Bonura, Giuseppe; Cannilla, Catia; Todaro, Serena; Cajumi, Alessandro
Erratum to: Promoting Direct CO2 Conversion to DME over Zeolite-based Hybrid Catalysts
2021 Frusteri, L.; Bonura, G.; Cannilla, C.; Todaro, S.; Giordano, G.; Migliori, M.; Frusteri, F.
Inside the reaction mechanism of direct CO2 conversion to DME over zeolite-based hybrid catalysts
2021 Bonura, G; Todaro, S; Frusteri, L; Majchrzakkucba, I; Wawrzyczak, D; Pászti, Z; Tálas, E; Tompos, A; Ferenc, L; Solt, H; Cannilla, C; Frusteri, F
Techno-economic feasibility of industrial production of biofuels by glycerol etherification reaction with isobutene or tert-butyl alcohol assisted by vapor-permeation membrane
2021 Cannilla, C; Giacoppo, G; Frusteri, L; Todaro, S; Bonura, G; Frusteri, F
Interaction effects between CuO-ZnO-ZrO2 methanol phase and zeolite surface affecting stability of hybrid systems during one-step CO2 hydrogenation to DME
2020 Bonura, G; Cannilla, C; Frusteri, L; Catizzone, E; Todaro, S; Migliori, M; Giordano, G; Frusteri, F
Promoting Direct CO2 Conversion to DME over Zeolite-based Hybrid Catalysts
2020 Frusteri, L.; Bonura, G.; Cannilla, C.; Todaro, S.; Giordano, G.; Migliori, M.; Frusteri, F.
Zeolite-assisted etherification of glycerol with butanol for biodiesel oxygenated additives production
2020 Cannilla, C.; Bonura, G.; Maisano, S.; Frusteri, L.; Migliori, M.; Giordano, G.; Todaro, S.; Frusteri, F.
Tailoring of Hydrotalcite-Derived Cu-Based Catalysts for CO2 Hydrogenation to Methanol
2019 Frusteri, L; Cannilla, C; Todaro, S; Frusteri, F; Bonura, G
| Titolo | Data di pubblicazione | Autore(i) | File |
|---|---|---|---|
| Metal-oxide interfaces and oxygen vacancies as dominant active sites in CO2 hydrogenation to methanol: Contrasting reactivity of Cu- and In-based functionalities | 1-gen-2026 | Todaro, S.; Arena, F.; Cannilla, C.; Corrente, C.; Cajumi, A.; Samperi, M.; Santoro, M.; Frusteri, F.; Bonura, G. | |
| 3D printed CuZnAl2O3-based catalysts for direct CO2 hydrogenation to DME, optimization and scale up | 1-gen-2024 | De Vos, Yoran; Koekkoek, Arie J. J.; Bonura, Giuseppe; Todaro, Serena; Kus, Monika; Vansant, Alexander; Gerritsen, Gijsbert; Cannilla, Catia; Abbenhuis, Hendrikus C. L.; Middelkoop, Vesna | |
| CO-PROX on MnO2 catalysts: DFT-based microkinetic and experimental macrokinetic approaches | 1-gen-2024 | Gueci, L.; Arena, F.; Todaro, S.; Bonura, G.; Cajumi, A.; Bertini, M.; Ferrante, F.; Nania, C.; Duca, D. | |
| Kinetic Modeling of the Direct Dimethyl Ether (DME) Synthesis over Hybrid Multi-Site Catalysts | 1-gen-2024 | D'Ambrosio, A.; Bertino, A.; Todaro, S.; Santoro, M.; Cannilla, C.; Frusteri, F.; Bonura, G.; Mazzeo, L.; Piemonte, V. | |
| Molecular dynamics and kinetic modelling of the CO and H2 oxidation pattern of a composite MnCeOx catalyst | 1-gen-2024 | Arena, Francesco; Ferrante, Francesco; Cajumi, Alessandro; Cannilla, Catia; Todaro, Serena; Bertini, Marco; Gueci, Laura; Bonura, Giuseppe; Pászti, Zoltán; Duca, Dario | |
| Unravelling the Influence of Binder Typology during the Additive Manufacturing of Hybrid Multi-Channel Cylinders for Catalytic Purposes | 1-gen-2024 | Todaro, S.; Bonura, G.; Cajumi, A.; Santoro, M.; Randazzo, F.; Giacoppo, G.; Frusteri, F.; Cannilla, C. | |
| Effectiveness of the 3D-printing procedure in the synthesis of hybrid catalysts for the direct hydrogenation of CO2 into dimethyl ether | 1-gen-2023 | Bonura, G; Todaro, S; Middelkoop, V; de Vos, Y; Abbenhuis, Hcl; Gerritsen, G; Koekkoek, Ajj; Cannilla, C; Frusteri, F | |
| Optimizing barium promoter for nickel catalyst supported on yttria-stabilized zirconia in dry reforming of methane | 1-gen-2023 | Al-Fatesh, A. S.; A, Ibrahim; Osman, A. I.; F, Albaqi; R, Arasheed; Frusteri, F.; Todaro, S.; K, Anojaidi; Lanre, M. S.; Abasaeed, A. E.; Fakeeha, A. H.; A, Bentalib; A., Bagabas | |
| Copper and Iron Cooperation on Micro-Spherical Silica during Methanol Synthesis via CO2 Hydrogenation | 1-gen-2022 | Todaro, S; Frusteri, F; Wawrzynczak, D; Majchrzakkuceba, I; Perezrobles, Jf; Cannilla, C; Bonura, G | |
| Membrane-assisted reactor for the direct conversion of CO2 to DME/MeOH | 1-gen-2022 | Frusteri, Francesco; Bonura, Giuseppe; Cannilla, Catia; Todaro, Serena; Cajumi, Alessandro | |
| Erratum to: Promoting Direct CO2 Conversion to DME over Zeolite-based Hybrid Catalysts | 1-gen-2021 | Frusteri, L.; Bonura, G.; Cannilla, C.; Todaro, S.; Giordano, G.; Migliori, M.; Frusteri, F. | |
| Inside the reaction mechanism of direct CO2 conversion to DME over zeolite-based hybrid catalysts | 1-gen-2021 | Bonura, G; Todaro, S; Frusteri, L; Majchrzakkucba, I; Wawrzyczak, D; Pászti, Z; Tálas, E; Tompos, A; Ferenc, L; Solt, H; Cannilla, C; Frusteri, F | |
| Techno-economic feasibility of industrial production of biofuels by glycerol etherification reaction with isobutene or tert-butyl alcohol assisted by vapor-permeation membrane | 1-gen-2021 | Cannilla, C; Giacoppo, G; Frusteri, L; Todaro, S; Bonura, G; Frusteri, F | |
| Interaction effects between CuO-ZnO-ZrO2 methanol phase and zeolite surface affecting stability of hybrid systems during one-step CO2 hydrogenation to DME | 1-gen-2020 | Bonura, G; Cannilla, C; Frusteri, L; Catizzone, E; Todaro, S; Migliori, M; Giordano, G; Frusteri, F | |
| Promoting Direct CO2 Conversion to DME over Zeolite-based Hybrid Catalysts | 1-gen-2020 | Frusteri, L.; Bonura, G.; Cannilla, C.; Todaro, S.; Giordano, G.; Migliori, M.; Frusteri, F. | |
| Zeolite-assisted etherification of glycerol with butanol for biodiesel oxygenated additives production | 1-gen-2020 | Cannilla, C.; Bonura, G.; Maisano, S.; Frusteri, L.; Migliori, M.; Giordano, G.; Todaro, S.; Frusteri, F. | |
| Tailoring of Hydrotalcite-Derived Cu-Based Catalysts for CO2 Hydrogenation to Methanol | 1-gen-2019 | Frusteri, L; Cannilla, C; Todaro, S; Frusteri, F; Bonura, G |