The direct synthesis of light olefins (C 2 H 4, C 3 H 6 and C 4 H 8) from syngas (a mixture of
H 2 and CO) could supply the extra resources of these platform building blocks for the …

Following the advances in capture technologies, CO2 utilization associated with low‐cost
renewable H2 in catalytic hydrogenation is a promising strategy for reducing the carbon …

Direct and selective conversion of syngas to higher alcohols (C 2+ OH, HA) is highly
attractive but remains challenges in improving the high catalytic performance. Herein, a …

Fischer–Tropsch to olefins (FTO) reaction is an important non-petrochemical route to
produce light olefins. Iron is the most widely used and easily obtainable metal catalyst with …

The promotion effect of manganese on the Ru-based Fischer–Tropsch to olefins (FTO)
reaction was investigated. Methane formation and second hydrogenation of olefins were …

The increasing demand in the chemical commodity industry and recognition of global
warming, necessitates a continuous search for alternative feedstocks and processes that …

The tuning of catalyst structures is a significant strategy to produce highly active catalysts.
Five primary methods were used herein to prepare NiCo composite catalysts, which were …

Hydroformylation is a prototypical CC coupling reaction of olefins and syngas to produce
valuable higher aldehydes. In this study, we investigated the promotional effect of potassium …

Direct CO 2 conversion to light olefins offers a chance to reduce CO 2 emission with
generating the revenue. However, a lack of efficient catalysts is a barrier for promoting this …

Syngas conversion provides an important platform for efficient utilization of various carbon-
containing resources such as coal, natural gas, biomass, solid waste and even CO2 …