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Synergistic performance of novel Cu-MOF-74@SBA-15 material in enhanced CO2 adsorption and transformation

Elena García-Rojas, Jesús Tapiador, Pedro Leo, Carmen Martos, Gisela Orcajo

2025Journal of CO2 Utilization18 citationsDOIOpen Access PDF

Abstract

Eight cost-effective MOF@OMM (Ordered Mesoporous Material) novel hybrid materials composed of SBA-15 and Cu-MOF-74 have been developed for CO₂ capture and conversion. Using a systematic synthesis approach, variables such as impregnation solvent, the copper molar concentration in the impregnation solution, and the MOF crystallization time were varied to find the material with the optimum features for CO 2 adsorption and transformation via cycloaddition reaction using epoxides. All synthesized materials were tested in CO 2 adsorption at 0 and 45°C to assess their CO 2 adsorption capacity at up to 8 bar. Remarkably, CO 2 adsorption per mmol of copper is higher for the hybrid Cu-MOF-74@SBA-15 materials than for the sole Cu-MOF-74 and SBA-15, revealing a cooperation effect between both structures. Additionally, as heterogeneous catalysts in CO₂ cycloaddition, the hybrids achieved higher epoxide conversion and turnover numbers than Cu-MOF-74 alone when the same catalyst mass was used. This improved performance comparable to pure MOF with less copper content is attributed to the enhanced dispersion and reduced crystal size of the MOF within the SBA-15 support, increasing accessibility to active sites and resulting in superior catalytic activity and CO₂ adsorption efficiency. This study highlights the potential of these hybrids as cost-effective, sustainable candidates for carbon mitigation solutions. • Novel synthesis route for Cu-MOF-74@SBA-15 with enhanced properties was developed. • Composites reduced MOF content, synthesis time, and cost vs. pristine Cu-MOF-74. • Synergy of Cu-MOF-74 and SBA-15 boosts CO2 adsorption per mmol of copper. • Hybrids showed better epoxide conversion and TON than Cu-MOF-74.

Topics & Concepts

AdsorptionTransformation (genetics)Chemical engineeringMaterials scienceChemistryPhysical chemistryBiochemistryEngineeringGeneMetal-Organic Frameworks: Synthesis and ApplicationsCatalytic Processes in Materials ScienceCarbon Dioxide Capture Technologies
Synergistic performance of novel Cu-MOF-74@SBA-15 material in enhanced CO2 adsorption and transformation | Litcius