To abate the environmental burdens arising from CO2 emissions, biochar offers a strategic means to sequester carbons dueto its recalcitrant nature. Also, biochar has a great potential for the use as carbon-based adsorbent because it is a porousmaterial. As such, developing the surface properties of biochar increases a chance to produce biochar with great adsorptionperformance. Given that biochar is a byproduct in biomass pyrolysis, characteristics of biochar are contingent on pyrolysisoperating parameters. In this respect, this work focused on the investigation of surface properties of biochar by controllingtemperature and reaction medium in pyrolysis of pine sawdust as case study. In particular, CO2 was used as reactionmedium in pyrolysis process. According to pyrolytic temperature, the surface properties of biochar were indeed developedby CO2. The biochar engineered by CO2 showed the improved capability on CO2 sorption. In addition, CO2 has an effecton energy recovery by enhancing syngas production. Thus, this study offers the functionality of CO2 for convertingbiomass into engineered biochar as carbon-based adsorbent for CO2 sorption while recovering energy as syngas.

1 Liu, Y., "Vermiculite modification increases carbon retention and stabil ity of rice straw biochar at different carbonization temperatures" 254 : 120111-, 2020

2 Lee, T., "Using CO2 as an Oxidant in the Catalytic Pyrolysis of Peat Moss from the North Polar Region" 54 (54): 6329-6343, 2020

3 Manyà, J. J., "Ultra-microporous adsorbents prepared from vine shoots-derived biochar with high CO2 uptake and CO2/N2 selectivity" 345 : 631-639, 2018

4 Muttakin, M., "Theoretical framework to evaluate minimum desorption tem-perature for IUPAC classified adsorption isotherms" 122 : 795-805, 2018

5 Dissanayake, P. D., "Sustainable gasification biochar as a high efficiency adsorbent for CO2 capture: A facile method to designer biochar fabrication" 124 : 109785-, 2020

6 Waters, C. L., "Staged thermal fractionation for segregation of lignin and cellulose pyrolysis products: An experimental study of resi-dence time and temperature effects" 126 : 380-389, 2017

7 Thakur, I. S., "Sequestration and utilization of carbon dioxide by chemical and biological methods for biofuels and biomaterials by chemoautotrophs: Opportunities and challenges" 256 : 478-490, 2018

8 Babin, A., "Potential and challenges of bioenergy with carbon capture and storage as a carbon-negative energy source: A review" 146 : 105968-, 2021

9 Mašek, O., "Potassium doping increases biochar carbon sequestration potential by 45%, facilitating decoupling of carbon sequestration from soil improvement" 9 (9): 5514-, 2019

10 Kumaravel, V., "Photoelectro-chemical Conversion of Carbon Dioxide (CO2) into Fuels and Value-Added Products" 5 (5): 486-519, 2020

11 Qiao, Y., "One-pot synthesis of digestate-derived biochar for car bon dioxide capture" 279 : 118525-, 2020

12 Kim, H. -B., "Mobility of arsenic in soil amended with biochar derived from biomass with different lignin contents: Relationships between lignin content and dissolved organic matter leaching" 393 : 124687-, 2020

13 Ramyashree, M. S., "Metal-organic framework-based photocatalysts for carbon dioxide reduction to methanol:A review on progress and application" 43 : 101374-, 2021

14 Lahijani, P., "Metal incorporated biochar as a potential adsorbent for high capacity CO2 capture at ambient condition" 26 : 281-293, 2018

15 Oginni, O., "Influence of high carbonization temperatures on microstructural and physicochemical character-istics of herbaceous biomass derived biochars" 8 (8): 104169-, 2020

16 Cao, Y., "Impacts of carbonization temperature on the Pb(II) adsorption by wheat straw-derived biochar and related mechanism" 692 : 479-489, 2019

17 Albanese, L., "Hydrodynamic cavitation as an energy efficient process to increase biochar surface area and porosity: A case study" 210 : 159-169, 2019

18 Rout, K. R., "Highly selective CO removal by sorption enhanced Boudouard reaction for hydro-gen production" 9 (9): 4100-4107, 2019

19 Saldarriaga, J. F., "Fast characterization of biomass fuels by thermogravimetric analysis (TGA)" 140 : 744-751, 2015

20 Mai, N. T., "Evolution of physico-chemical properties of Dicranopteris linearis-derived activated carbon under various physical activation atmospheres" 11 (11): 14430-, 2021

21 de la Rosa, J. M., "Effects of aging under field conditions on biochar structure and composition: Implications for biochar sta-bility in soils" 613 (613): 969-976, 2018

22 Wani, I., "Effect of pH, volatile content, and pyrolysis conditions on surface area and O/C and H/C ratios of biochar: Towards under-standing performance of biochar using simplified approach" 24 (24): 04020048-, 2020

23 Lee, D. -J., "Direct conversion of yellow mealworm larvae into biodiesel via a non-catalytic transesterification platform" 427 : 131782-, 2022

24 Lahijani, P., "Conversion of the greenhouse gas CO2 to the fuel gas CO via the Boudouard reaction: A review" 41 : 615-632, 2015

25 Yu, H., "Catalytic gasification char acteristics of cellulose, hemicellulose and lignin" 121 : 559-567, 2018

26 Creamer, A. E., "Carbon dioxide capture using various metal oxyhydroxide–biochar composites" 283 : 826-832, 2016

27 Shahkarami, S., "Breakthrough CO2 adsorption in bio-based activated carbons" 34 : 68-76, 2015

28 Leng, L., "Biochar stability assessment methods: A review" 647 : 210-222, 2019

29 Kwak, J. -H., "Biochar properties and lead(II) adsorption capacity depend on feedstock type, pyrolysis temperature, and steam activation" 231 : 393-404, 2019

30 Lee, J., "Biochar as a Cata-lyst" 77 : 70-79, 2017

31 Leng, L., "An overview of the effect of pyrolysis process parameters on biochar stability" 270 : 627-642, 2018

32 Budinis, S., "An assessment of CCS costs, barriers and potential" 22 : 61-81, 2018