Real-time monitoring of alkali release during CO2 gasification of different types of biochar

Potassium and sodium compounds play both positive and negative roles during biomass gasification, but the detailed behavior of alkali metal compounds remain incompletely understood. In this study, alkali release during CO2 gasification of biochar is characterized online with a surface ionization method in combination with thermogravimetric analysis of the char samples undergoing gasification. For wood chars, the alkali release rate follows a slowly decreasing trend as the char conversion proceeds, but increases by up to two orders of magnitude when the conversion approaches completion. In contrast, the alkali release from straw char is 40-50 times higher than observed for wood char and decreases continuously during the whole gasification process. A high temperature and a high CO2 concentration enhance both alkali release and char reactivity. The char preparation method also influences the alkali release from pine char, while the char reactivity is less affected. Alkali release and char reactivity are linked, but other factors including mineral content, surface area and char structure may play important roles for the observed reactivity. The results provide a basis for understanding of alkali behavior during gasification and may help optimize catalytic effects and reduce detrimental issues in biomass gasification.

Automated summary

This study characterizes the alkali release during CO2 gasification of biochar using a surface ionization method combined with thermogravimetric analysis. The results show that alkali release rate from wood char decreases as char conversion proceeds, but increases significantly when conversion approaches completion. On the other hand, alkali release from straw char is much higher and decreases continuously during gasification. High temperature and high CO2 concentration enhance alkali release and char reactivity.