artículo académico

• CO2 Methanation Routes on Ni, Co, and NiCo (111) and (100) Surfaces.  CHEMPHYSCHEM.  2025
• Effect of the Sr substitution in the A-site for La1-xSrxCoO3 perovskite catalysts for the valorization of levulinic acid to produce gamma-valerolactone.  CATALYSIS TODAY.  450. 2025
• Hydrogenation of 4-(2-furyl)-3-buten-2-one using Cu-double layered hydroxides modified with Zr and Ce.  APPLIED CATALYSIS A-GENERAL.  704. 2025
• Study of the surface species of CePr-supported Cu, Ni and CuNi catalysts at different Water Gas Shift reaction conditions.  JOURNAL OF CATALYSIS.  448. 2025
• Unveiling the pathways and site requirements of methanol oxidative dehydrogenation on MoO3/TiO2 catalysts: An operando-FTIR study.  JOURNAL OF CATALYSIS.  447. 2025
• A detailed kinetic model for the methanol oxidative dehydrogenation on vanadia-based catalysts: Aggregation state role and active site requirements.  APPLIED CATALYSIS A-GENERAL.  628. 2024
• A review: Rational design of catalysts for catalytic decomposition of ammonia.  INTERNATIONAL JOURNAL OF HYDROGEN ENERGY.  90:1435-1466. 2024
• Assessing Thermodynamics Models for Phase Equilibria and Interfacial Properties Relevant to the Hydrogenation of Carbon Dioxide.  INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH.  63(27):12235-12249. 2024
• Cobalt-based core@shell catalysts for guaiacol hydro conversion: use of salicylic acid as a sacrificial modulator of the interaction between the metal phase and the silica support.  NEW JOURNAL OF CHEMISTRY.  48(3):14056-14066. 2024
• Furfural adsorption on V2O5 surface: A combined experimental-theoretical study.  CHEMICAL PHYSICS LETTERS.  845. 2024
• Interdependence Between the Extent of Ga Promotion, the Nature of Active Sites, and the Reaction Mechanism Over Cu Catalysts for CO2 Hydrogenation to Methanol.  ACS CATALYSIS.  14(20):15265-15278. 2024
• On the Structure Sensitivity of CO2 Hydrogenation over Cu/ZrO2: Insights into the Role of the Support and the Active Sites.  ACS CATALYSIS.  14(18):14127-14138. 2024
• Unraveling the mechanistic interplay between CO and CO2 hydrogenation over Ni, Co, and NiCo catalysts.  JOURNAL OF CATALYSIS.  438. 2024
• VO Supported on Functionalized CNTs for Oxidative Conversion of Furfural to Maleic Anhydride.  CATALYSTS.  14(8). 2024
• Combined role of Ce promotion and TiO2 support improves CO2 hydrogenation to methanol on Cu catalysts: Interplay between structure and kinetics.  JOURNAL OF CATALYSIS.  426:200-216. 2023
• Disclosing the Reaction Mechanism of CO2 Hydrogenation to Methanol over CuCeOx/TiO2: A Combined Kinetic, Spectroscopic, and Isotopic Study.  ACS CATALYSIS.  13(22):14699-14715. 2023
• Effects of Site Geometry and Local Composition on Hydrogenation of Surface Carbon to Methane on Ni, Co, and NiCo Catalysts.  CATALYSTS.  12(11). 2023
• Elucidating the promotional effect of ultra-low Zn content on Cu for CO2 hydrogenation to methanol.  JOURNAL OF CATALYSIS.  427. 2023
• Isotopic transient kinetic analysis of CO2 hydrogenation to methanol on Cu/SiO2 promoted by Ga and Zn.  JOURNAL OF CATALYSIS.  406:96-106. 2022
• Scrutinizing the mechanism of CO2 hydrogenation over Ni, CO and bimetallic NiCo surfaces: Isotopic measurements, operando-FTIR experiments and kinetics modelling.  JOURNAL OF CATALYSIS.  414:1-15. 2022
• Kinetic and structural understanding of bulk and supported vanadium-based catalysts for furfural oxidation to maleic anhydride.  CATALYSIS SCIENCE & TECHNOLOGY.  11(19):6477-6489. 2021
• CO2 Hydrogenation to Methanol with Ga- and Zn-Doped Mesoporous Cu/SiO2 Catalysts Prepared by the Aerosol-Assisted Sol-Gel Process.  CHEMSUSCHEM.  13(23):6409-6417. 2020
• The consequences of support identity on the oxidative conversion of furfural to maleic anhydride on vanadia catalysts.  APPLIED CATALYSIS A-GENERAL.  595. 2020
• The nature of the active sites of Pd-Ga catalysts in the hydrogenation of CO(2)to methanol.  CATALYSIS SCIENCE & TECHNOLOGY.  10(19):6644-6658. 2020
• Insights into the role of Zn and Ga in the hydrogenation of CO2 to methanol over Pd.  INTERNATIONAL JOURNAL OF HYDROGEN ENERGY.  44(31):16526-16536. 2019
• Mechanism and structure sensitivity of methanol synthesis from CO2 over SiO2-supported Cu nanoparticles.  JOURNAL OF CATALYSIS.  369:415-426. 2019
• The consequences of surface heterogeneity of cobalt nanoparticles on the kinetics of CO methanation.  CATALYSIS SCIENCE & TECHNOLOGY.  9(22):6415-6427. 2019
• The kinetic effect of H2O pressure on CO hydrogenation over different Rh cluster sizes.  INTERNATIONAL JOURNAL OF HYDROGEN ENERGY.  44(2):768-777. 2019
• Catalytic consequences of Ga promotion on Cu for CO2 hydrogenation to methanol.  CATALYSIS SCIENCE & TECHNOLOGY.  7(15):3375-3387. 2017
• A modelling approach to the techno-economics of Biomass-to-SNG/Methanol systems: Standalone vs integrated topologies.  CHEMICAL ENGINEERING JOURNAL.  286:663-678. 2016
• New concepts in low-temperature catalytic hydrogenation and their implications for process intensification.  CANADIAN JOURNAL OF CHEMICAL ENGINEERING.  94(4):662-677. 2016
• CO2 hydrogenation with shape-controlled Pd nanoparticles embedded in mesoporous silica: Elucidating stability and selectivity issues.  CATALYSIS COMMUNICATIONS.  58:11-15. 2015
• Kinetic and in situ ftir study of co methanation on a rh/al2o3 catalyst.  CATALYSIS SCIENCE & TECHNOLOGY.  5(9):4532-4541. 2015
• The role of copper particle size in low pressure methanol synthesis via CO2 hydrogenation over Cu/ZnO Catalysts.  CATALYSIS SCIENCE & TECHNOLOGY.  5:869-881. 2015
• Oxidation of methanol to methyl formate over supported Pd nanoparticles: insights into the reaction mechanism at low temperature.  CATALYSIS SCIENCE & TECHNOLOGY.  4(9):3298-3305. 2014