Conversion of syngas to olefins and green hydrocarbons through Fischer–Tropsch catalysis

“…As an alternative, many studies investigate its employment as a precursor for chemical products or hydrogen sources, which, however, require the separation between hydrogen and the other components through membranes or similar technologies [25]. In the relevant literature, two main pathways for turning syngas into energy are usually discussed: (1) converting syngas to biogas [26], hydrogen [27], or liquid fuels through fermentation and the Fischer-Tropsch process [28]; and (2) direct use of syngas for power generation [29]. The direct energy production from syngas leads to some advantages, such as the avoidance of a highly energy-intensive process of pressurization, which is necessary when syngas is catalytically converted into chemicals [30].…”

Life Cycle Assessment of a Wood Biomass Gasification Plant and Implications for Syngas and Biochar Utilization

“…As an alternative, many studies investigate its employment as a precursor for chemical products or hydrogen sources, which, however, require the separation between hydrogen and the other components through membranes or similar technologies [25]. In the relevant literature, two main pathways for turning syngas into energy are usually discussed: (1) converting syngas to biogas [26], hydrogen [27], or liquid fuels through fermentation and the Fischer-Tropsch process [28]; and (2) direct use of syngas for power generation [29]. The direct energy production from syngas leads to some advantages, such as the avoidance of a highly energy-intensive process of pressurization, which is necessary when syngas is catalytically converted into chemicals [30].…”

Life Cycle Assessment of a Wood Biomass Gasification Plant and Implications for Syngas and Biochar Utilization