Themed collection CO2 Conversion

This perspective reflects on the implementation of a multidisciplinary consortium project combining biological, chemical and computational sciences to discover and develop new enzymes for carbon dioxide fixation.

Carboxylation is a promising and versatile technology for producing industrially valuable products, being a potential process for future use of captured CO₂. Enzymatic and thermochemical routes are the closest to being scaled up.

Catalytic reduction of CO₂ to methane conversion by single-atom catalysts (SACs).

Dry reforming of methane on CeNiO₃ nanoparticles.

Effects of pre-treatment temperatures on the catalytic activity of a Ni-doped perovskite for dry reforming of methane were studied. Particles form at optimal temperatures that are stable under reaction conditions, shown by in situ XRD measurements.

Optimizing calcium and magnesium extraction from platinum group metal mine tailings for enhanced CO₂ storage via a pH-swing process.

CO₂ and CO valorization to methanol and methane over Cu or CuPd nanoparticles supported on ZnO or graphene. The catalysts demonstrate high efficiency, favouring methane at lower metal loading but methanol at high copper content.

With the growing necessity of achieving carbon neutrality in the industrial sector, the catalytic hydrogenation of carbon dioxide into methanol has been widely considered one of the key strategies for the utilization of captured CO₂.

2,5-Furan Dicarboxylic Methyl Ester (FDME) was obtained from CO₂ and methyl furoate using a cobalt-based heterogeneous catalyst prepared by mechanochemical polymerization. FDME was validated in the synthesis of a biopolyester.

An integrated CO₂ capture and conversion system utilizing metal hydroxide salts has been developed to capture CO₂ from various sources including air in the form of carbonate salts and convert them directly into a synthetic fuel; methane.

Ultraporous permanently polarized hydroxyapatite catalysts are successfully used as an alternative to conventional industrial catalysts for the production of value-added chemical products from CO₂ under truly sustainable and green conditions.

An ionic liquid polymeric matrix is used to immobilize a ruthenium photosensitizer and rhenium catalyst for selective CO₂ reduction to CO.

BaTiO₃ nanocatalysts chemisorb and reduce CO₂ efficiently at 700 K and 0.1–1.0 MPa.

A xanthphos-based porous organic polymer enables the support of a molecular ruthenium complex as solid catalyst for the hydrogenation of CO₂ to formic acid as renewable platform chemical.