Table 1.
Study | Process | Product applications | GHG emissions reduction intensity (g CO2-eq MJ−1) |
---|---|---|---|
This study |
Biomass pyrolysis poly-generation system Temperature: 600 °C Residence time: >1800 s |
Biochar: soil application Pyrolysis gas: substitution of coke oven gas and electricity production Bio-oil: substitution of coal tar in chemical raw materials |
136.45 |
Biochar: charcoal substitution in industries Pyrolysis gas: substitution of coke oven gas and electricity production Bio-oil: substitution of coal tar in chemical raw materials |
46.80 | ||
Peters et al.28 (Spain) |
Biomass slow pyrolysis system Temperature: 450 °C Residence time: ~2500 s |
Biochar: soil application Pyrolysis gas: heat production for pyrolysis system and substitution of natural gas Bio-oil: heat production for pyrolysis system |
122.18 |
Biochar: charcoal substitution in coal power plant Pyrolysis gas: heat production for pyrolysis system and substitution of natural gas Bio-oil: heat production for pyrolysis system |
63.22a | ||
Roberts et al14. (the United States) |
Biomass slow pyrolysis system Temperature: 450 °C Residence time: long enough |
Biochar: soil application Pyrolysis gas: substitution of natural gas for heat product |
108.57 |
Biochar: charcoal substitution in IGCC plant Pyrolysis gas: substitution of natural gas for heat product |
36.64 |
aThe reference does not consider the GHG emissions derived from construction process (e.g., equipment and installation) in life-cycle assessment.