New Catalyst for Propylene Synthesis with Carbon Recycling Benefits

TAGS:  Sustainability / Natural Coatings    

Researchers at Hokkaido University have developed an innovative catalyst for the production of propylene that is highly active, selective, stable and utilizes carbon dioxide (CO₂) efficiently.

Converting Propane Gas Into Propylene

One promising technique for producing propylene is a chemical reaction, called oxidative dehydrogenation, that uses CO₂ to convert propane gas into propylene by removing hydrogen. However, existing catalysts used to speed up this chemical reaction aren’t very efficient.

“The challenge is to develop a catalyst that will activate both reactants – propane and CO₂ – without unwanted side reactions. It also needs to be stable and reusable in the long term,” explains Hokkaido University molecular engineer, Shinya Furukawa.

To achieve this, Furukawa and his colleagues developed a catalyst made from three different metals (platinum, cobalt and indium), each chosen for its specific properties. Platinum was selected as the main active metal because of its ability to break chemical bonds between carbon and hydrogen, enabling the dehydrogenation reaction.

Cobalt accelerates CO₂ capture and activation, while indium enhances the catalyst’s selectivity. The metals were fixed to a support made from cerium oxide, a compound commonly used in car catalytic converters.

Mechanism of Catalytic Action

Platinum converts propane (C3H8) to form propylene (C3H6), while cobalt captures and activates CO₂. When mixed together with indium and fixed on a cerium oxide support (CeO), the formation of propylene is linked to the deoxygenation of CO₂ and is specific to propane. Water (H₂O) and carbon oxides (COx) are formed as byproducts (Shinya Furukawa).

The researchers tested the catalyst’s activity at 550°C and compared the results with existing catalysts.

They also performed a mechanistic study to understand the functions of the different components and found the catalyst links the propylene-forming reaction to the deoxygenation of CO₂,and ensures the catalytic activity is specific to propane; water and carbon oxides are formed as byproducts.

Further, they found that the catalyst increased the reaction rate approximately five fold compared to the typical values reported from other systems. The reaction produced a higher ratio of propylene and utilized more CO₂ at 550°C compared to previous catalysts. The catalyst also showed good long-term stability and reusability.

“To date, no other catalyst has been shown to simultaneously exhibit a high catalytic activity, selectivity, stability, and CO₂ utilization efficiency. Our multifunctional material meets all these requirements,” says Furukawa.

This study provides new insights into the design of highly efficient catalysts for petrochemical production, and has potential benefits for carbon recycling and greenhouse gas reduction.

Source: Hokkaido University