Porous Biochars Derived from Microalgae Pyrolysis for CO2 Adsorption

In order to slow down the greenhouse warming caused by excessive CO2 emissions and effectively exploit the byproducts produced during the biofuel production process, N-doped porous biochars derived from the byproducts of microalgae (chlorella and spirulina) pyrolysis by combining urea and KOH modification were synthesized in this article to remove CO2 in simulated flue gas. The physicochemical properties of the microalgae porous biochars were investigated via characterization tools, involving pH, Brunauer-Emmett-Teller (BET), scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS), and Fourier-transform infrared spectroscopy (FTIR). CO2 adsorption kinetics, thermodynamics, and CO2 adsorption performance were also studied. Results reveal that the functional groups and specific surface areas of microalgae biochars are substantially increased via urea and KOH modification, and nitrogen-containing functional groups (mainly involving N-H, C-N, etc.) are major adsorption sites for CO2 adsorption. The key control step for CO2 adsorption is external mass transfer, and the CO2 adsorption process over the microalgae porous biochars is mainly physical adsorption. Moreover, the chlorella-based porous biochars CNK-2 and spirulina-based porous biochars SNK-2 have optimal CO2 removal performances, and their maximum adsorption capacities, respectively, reach 3.44 and 3.09 mmol/g at 25 degrees C. The results of regeneration studies demonstrate that, after 10 regeneration experiments, CNK-2 and SNK-2 still possess high CO2 sorption performances (reaching 3.09 and 2.78 mmol/g, respectively), exhibiting good regeneration potential.

Automated summary

N-doped porous biochars derived from microalgae byproducts synthesized using urea and KOH modification are effective in CO2 adsorption, showing good regeneration potential and high CO2 adsorption capacity.