Synthesis of liquid biofuels from biomass by hydrothermal gasification: A critical review

Liquid transportation biofuel production is a promising strategy to reduce greenhouse gas emissions. Hydrothermal gasification (HTG) has shown great potential as an effective method for valorizing wet biomass. The high-quality syngas produced using the HTG process can be chemically/biochemically converted to liquid biofuels. Therefore, this paper aims to comprehensively review and critically discuss syngas production from biomass using the HTG process and its conversion into liquid biofuels. The basics and mechanisms of biomass HTG processing are first detailed to provide a comprehensive and deep understanding of the process. Second, the effects of the main operating parameters on the performance of the HTG process are numerically analyzed and mechanistically discussed. The syngas cleaning/conditioning and Fischer-Tropsch (FT) synthesis are then detailed, aiming to produce liquid biofuels. The economic performance and environmental impacts of liquid biofuels using the HTG-FT route are evaluated. Finally, the challenges and prospects for future development in this field are presented. Overall, the maximum total gas yield in the HTG process is obtained at temperature, pressure, and residence time in the range of 450-500 degrees C, 28-30 MPa, and 30-60 min, respectively. The highest C5+ liquid hydrocarbon selectivity in the FT process is achieved at temperatures between 200 and 240 degrees C. Generally, effective conversion of biomass to syngas using the HTG process and its successful upgrading using the FT process can offer a viable route for producing liquid biofuels. Future studies should use HTG technology in the biorefinery context to maximize biomass valorization and minimize waste generation.

Automated summary

This paper comprehensively reviews and critically discusses the process of producing syngas from biomass using the HTG process and its conversion into liquid biofuels. The paper details the basics and mechanisms of biomass HTG processing, analyzes the effects of main operating parameters on the performance of the HTG process, and evaluates the economic performance and environmental impacts of using the HTG-FT route to produce liquid biofuels. The paper concludes that effective conversion of biomass to syngas using the HTG process and its successful upgrading using the FT process offer a viable route for producing liquid biofuels.