Catalysis remains a cornerstone of contemporary chemical research and industrial applications, with zeolite materials at its forefront due to their unique microporous structures and tunable chemical ...

Platinum-based catalysts supported on zeolite frameworks combine the unique acidity and confinement effects of molecular sieves with the redox and hydrogenation–dehydrogenation capabilities of ...

In light of the waste-to-wealth movement, technology for converting greenhouse gases into value-added materials has gained significant attention in recent years. One such technology is the catalytic ...

The optimal design of a novel zeolite catalyst enables tandem reaction that turns greenhouse gases into value-added chemicals, report scientists. By tuning the separation between different active ...

Zeolites have been widely applied in the fields of adsorption, ion exchange, and catalysis due to their uniform micropores, tunable active sites, high adsorption capacity, and excellent thermal and ...

For viable commercial application, catalysts of any type—heterogeneous, homogeneous, or enzymatic—must exhibit a number of properties, the principal ones being high activity, selectivity, durability, ...

Catalysis is a fundamental concept in the areas of chemical, physical, and biological sciences, evolving over the years. The primary function of a catalyst is to decrease the activation energy and ...

A chemical reaction can convert two polluting greenhouse gases into valuable building blocks for cleaner fuels and feedstocks, but the high temperature required for the reaction also deactivates the ...

2024 was predicted to be the hottest year on record, with global temperatures exceeding 1.5 °C above pre-industrial levels for the first time. Numerous organizations, industries, and nations have ...