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Rational Design of Catalyst Supports for CO<sub>2</sub> Hydrogenation to Light Olefins: Structural, Electronic, and Stabilization Strategies

Yanyan Zhang, Yunzhu Ma, Ying Cao, Jian Gao, Chunshan Song

2025Energy & Fuels8 citationsDOI

Abstract

The rational design of catalyst supports represents a critical strategy for enhancing the hydrogenation of CO 2 into Light Olefins (C 2 –C 4 ), significantly impacting key performance indicators such as activity, selectivity, and stability. This review comprehensively examines three foundational mechanisms through which support materials influence catalytic outcomes: (1) structural modulation: hierarchically porous architectures with high specific surface areas improve active-phase dispersion and facilitate mass transport, thereby optimizing reaction kinetics. (2) electronic engineering: metal–support interactions (MSIs) enhance CO 2 chemisorption, promoting C–C coupling kinetics and favoring selective olefin formation. (3) stabilization strategies: oxide matrices (e.g., ZrO 2, Al 2 O 3 ) effectively suppress metal sintering, while carbonaceous supports minimize coking via ordered mesoporosity. Moreover, hydrophobic surfaces accelerate H 2 O desorption, reducing aqueous-phase oxidation. Additionally, acid–based properties regulate reaction pathways: Lewis acid-dominated surfaces encourage chain growth, whereas moderate basicity facilitates CO 2 activation. These structure–activity relationships establish a robust foundation for designing advanced catalysts for CO 2 -to-olefin conversion with atomic-level precision.

Topics & Concepts

Rational designCatalysisOlefin fiberDispersion (optics)Materials sciencePorosityChemical engineeringOxideNanotechnologyKineticsHeterogeneous catalysisMetalCombinatorial chemistryReaction conditionsCoupling (piping)ChemistrySupport surfaceNOxDesign elements and principlesMoleculeLewis acids and basesCarbon dioxide utilization in catalysisCatalysts for Methane ReformingCO2 Reduction Techniques and Catalysts
Rational Design of Catalyst Supports for CO<sub>2</sub> Hydrogenation to Light Olefins: Structural, Electronic, and Stabilization Strategies | Litcius