[2] BHATT K P, PATEL S, UPADHYAY D S et al. A critical review on solid waste treatment using plasma pyrolysis technology[J]. Chemical Engineering and Processing - Process Intensification, 177, 108989.(2022).

[4] SINGH G, LAKHI, K S, SIL S et al. Biomass derived porous carbon for CO2 capture[J]. Carbon, 148, 164-186.(2019).

[5] YANG G Z, SONG S, LI J et al. Preparation and CO2 adsorption properties of porous carbon by hydrothermal carbonization of tree leaves[J]. Journal of Materials Science & Technology, 35, 875-884(2019).

[6] RAO L L, LIU S F, WANG L L et al. N-doped porous carbons from low-temperature and single-step sodium amide activation of carbonized water chestnut shell with excellent CO2 capture performance[J]. Chemical Engineering Journal, 359, 428-435(2019).

[8] GHOLIDOUST A, ATKINSON J D, HASHISHO Z. Enhancing CO2 adsorption via amine impregnated activated carbon from oil sands coke[J]. Energy Fuels, 31, 1756-1763(2017).

[10] IDRESS M, RANGARI V, JEELANI S. Sustainable packaging waste-derived activated carbon for carbon dioxide capture[J]. Journal of CO₂ Utilization, 26, 380-387(2018).

[11] HAN J, ZHANG L, ZHAO B et al. The N-doped activated carbon derived from sugarcane bagasse for CO2 adsorption[J]. Industrial Crops and Products, 128, 290-297(2019).

[12] HE S, CHEN G Y, XIAO H et al. Facile preparation of N-doped activated carbon produced from rice husk for CO2 capture[J]. Journal of Colloid and Interface Science, 582, 90-101.(2021).

[13] MAROS J P, SILVLA C O, FRANCISCO R R et al. Tailoring low cost granular activated carbons intended for CO2 adsorption[J]. Frontiers in Chemistry, 581133-581148(2020).

[14] MOHAMMED M. Synthesis and characterization of high-performance activated carbon from walnut shell biomass for CO2 capture[J]. Environmental Science and Pollution Research, 27, 15020-15028(2020).

[15] KHUONGAB D A, NGUYEN H N, TSUBOTA T et al. Activated carbon produced from bamboo and solid residue by CO2 activation utilized as CO2 adsorbents[J]. Biomass Bioenergy, 148, 106039-106045(2021).

[16] XU Y, YANG Z X, ZHANG G J et al. Excellent CO2 adsorption performance of nitrogen-doped waste biocarbon prepared with different activators[J]. Journal of Cleaner Production, 264, 121645.(2020).

[17] DENG S B, WEI H R, CHEN T et al. Superior CO2 adsorption on pine nut shell-derived activated carbons and the effective micropores at different temperatures[J]. Chemical Engineering Journal, 253, 46-54.(2014).

[18] YANG M, GUO L, HU G et al. Highly cost-effective nitrogen-doped porous coconut shell-based CO2 sorbent synthesized by combining ammoxidation with KOH activation[J]. Environmental Science & Technology, 49, 7063-7070(2015).

[19] SHAFEEYAN M S, DAUD W M A W, HOUSHMAND A et al. Ammonia modification of activated carbon to enhance carbon dioxide adsorption: Effect of pre-oxidation[J]. Applied Surface Science, 257, 3936-3942(2011).

[20] OH W D, LISAK G, WEBSTER R D et al. Insights into the thermolytic transformation of lignocellulosic biomass waste to redox-active carbocatalyst: Durability of surface active sites[J]. Applied Catalysis B: Environmental, 233, 120-129(2018).

[21] MISHRA R K, MISRA M, MOHANTY A K. Value-added bio-carbon production through the slow pyrolysis of waste bio-oil: Fundamental studies on their structure–property–processing co-relation[J]. ACS Omega, 7, 1612-1627(2022).

[22] RO A, TY B, JNK B. Probing the basicity of lattice oxygen on H-form zeolites using CO2[J]. Journal of Catalysis, 371, 291-297.(2019).