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Engineering nitrogen and oxygen functionalities in naturally sourced activated carbon for multicomponent gas adsorption

Xiupeng Cheng, Zhipeng Qie, Huaizhong Xiang, Zhongbao Liu, Limingxin Zong, Wenqi He, Xinxin Pi, Hassan Alhassawi, Peng Cao, Guang Yang, Shuangshuang Gao

2025Scientific Reports15 citationsDOIOpen Access PDF

Abstract

Abstract Nitrogen doping is a widely adopted strategy to enhance the gas adsorption performance of activated carbon (AC) adsorbents. However, the simultaneous evolution of oxygen and nitrogen functional groups—especially in carbon precursors with high oxygen content—has received limited attention. In this study, coal-derived ACs with high surface areas (up to 940 m 2 /g) and micropore volumes (0.36 cm 3 /g) were synthesized via K 2 CO 3 -assisted physical activation, followed by nitrogen doping through co-pyrolysis with melamine. By regulating the doping temperature (600–900 °C), the nitrogen content of the resulting samples ranged from 1.44 to 7.68 at%, while the oxygen content varied from 6.89 to 10.39 at%. After decoupling the influences of porosity, we found that a well-balanced distribution of N and O functionalities, especially pyrrolic nitrogen, ether (C–O–C), and hydroxyl (C–O–H) groups, was critical for enhancing CO 2 and H 2 O adsorption. NAC-600 exhibited the most favorable surface chemistry for the adsorption of CO 2 (15 vol%) and H 2 O (20% RH), achieving capacities of 41 mg/g and 59.9 mg/g, respectively. In contrast, NAC-900, prepared at the highest N-doping temperature, exhibited the best surface chemistry for toluene adsorption (550 mg/cm 3 ), attributed to its higher degree of graphitization and the presence of graphitic N and ether groups. This work offers a rational design strategy for improving the multicomponent gas adsorption performance of activated carbons for flue gas treatment.

Topics & Concepts

AdsorptionFlue gasNitrogenActivated carbonOxygenPyrolysisChemistryMicroporous materialCarbon fibersTolueneChemical engineeringInorganic chemistryOrganic chemistryMaterials scienceEngineeringComposite materialComposite numberCarbon Dioxide Capture TechnologiesMembrane Separation and Gas TransportCatalytic Processes in Materials Science
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