Effects of sludge pyrolysis temperature and atmosphere on characteristics of biochar and gaseous products

In view of the importance of inert-atmosphere sludge pyrolysis for effective waste recycling and carbon emission reduction, this study probed the effects of temperature (300-700 degrees C) and atmosphere (100% N-2, 10 CO2/90% N-2, or 100% CO2) on the properties of biochar and gases obtained by sludge pyrolysis in a horizontal tube furnace. The emissions of NO, SO2, H2S, and CO increased with increasing temperature, as the inhibitory effect of CO2 on the formation of these gases (observed at <500 degrees C) concomitantly weakened and was superseded by the reaction of CO2 with carbon at higher temperature to afford gaseous products. The specific surface area (S-BET) and pore volume of the biochar produced in the presence of CO2 increased with increasing temperature up to 500 degrees C, while at higher temperatures the inhibitory effect of CO2 on pore structure development resulted in a decreased S-BET and an increased macropore content. These results show that pyrolysis is an effective treatment method for sludge; it can remove 48% N and 50% S in sludge and mitigate the emission of polluting gases. When CO2 participates in the pyrolysis reaction, the S-BET of biochar increases significantly. In general, sludge biochar has the potential to be applied as fuel and as an adsorbent.

Automated summary

This study investigated the effects of temperature and atmosphere on the properties of biochar and gases obtained by sludge pyrolysis, finding that CO2 has both inhibitory and enhancing effects on gas formation at different temperature ranges. The interaction between CO2 and carbon also affects the pore structure development of biochar. Pyrolysis is shown to be an effective method for treating sludge, with the potential for biochar to be used as fuel and an adsorbent.