A systematic review on hydrogen production via hydrochar-based gasification
Sabah Mariyam, Mohammad Alherbawi, Gordon McKay, Tareq Al‐Ansari
Abstract
Hydrogen (H 2 ) yields from various gasification and hydrothermal processes demonstrate significant variability depending on feedstock, catalysts, and process parameters. This systematic review explores hydrogen production through hydrochar-based gasification technologies, focusing on the unique properties of hydrochar derived from biomass. Known for its ability to enhance syngas production, especially hydrogen, hydrochar's porous structure, high surface area, and active catalytic sites significantly improve syngas quality and hydrogen yield. Studies show that supercritical water gasification (SCWG) of almond shells with hydrochars yielded up to 11.63 mmol/g, while catalytic subcritical and SCWG of waste tires reached 19.7 mmol/g. Hydrothermal carbonization (HTC) coupled with gasification yields as high as 76.7 g H 2 /kg biochar for sewage sludge hydrochar, with processes like anaerobic digestion and HTC producing 1278 mL/g from hemp hurd hydrochar. Key aspects such as the catalytic influence of hydrochar, the role of additives and co-catalysts, and optimization of gasification parameters, including temperature, pressure, and equivalence ratios, are explored. The review also delves into hydrochar preparation advancements, such as alkali and alkaline earth metals (AAEMs) incorporation, and highlights hydrochar's role in reducing tar formation, enhancing H 2 /CO ratios, and stabilizing syngas heating value. • Hydrochar’s porosity and carbon content boost H₂-rich syngas yields. • HTC with SCWG or AD improves H₂ yield, syngas quality, and tar control. • Metal-doped hydrochar catalysts enhance H₂ selectivity and reduce coke. • Optimal HTC at 200–240 °C, gasification at 900–1050 °C with steam/O₂. • Scale-up needs better reactors, catalyst regeneration, and policy support.