One-step synthesis of microporous nitrogen-doped biochar for efficient removal of CO2 and H2S

[Display omitted] •One-step method for preparation of microporous N-doped biochar from plant biomass.•Urea phosphate as both activator and nitrogen source during pyrolysis.•The prepared biochar has the efficient removal of both CO2 and H2S. It is still a great challenge to prepare an ideal adsorbent...

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Bibliographic Details
Published inFuel (Guildford) Vol. 289; p. 119932
Main Authors Ma, Qiuxu, Chen, Wenhua, Jin, Ziheng, Chen, Lin, Zhou, Qiying, Jiang, Xia
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.04.2021
Elsevier BV
Subjects
Adsorbents
Adsorption
Biochar
Biogas
Carbon dioxide
Charcoal
CO2 adsorption
Desulfurization
Functional groups
Hydrogen sulfide
N-doping
Nitrogen
Phosphoric acid
Plant biomass
Surface chemistry
Synthesis
Urea
Urea phosphate
Urea phosphate
Desulfurization
Biochar
N-doping
CO2 adsorption
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Summary:[Display omitted] •One-step method for preparation of microporous N-doped biochar from plant biomass.•Urea phosphate as both activator and nitrogen source during pyrolysis.•The prepared biochar has the efficient removal of both CO2 and H2S. It is still a great challenge to prepare an ideal adsorbent for the removal of CO2 and H2S from biogas efficiently. In this study, urea phosphate (UP) was selected as both activator and nitrogen (N) source to prepare the biochar adsorbent from plant biomass with microporous structure and N-rich functional groups through “one-step” synthesis. The results show that the yield of biochar increased from about 20% to 50%, and the SBET and Vmic of the obtained biochar were 1189 m2/g and 0.433 cm3/g, respectively, which was much higher than those without UP addition (524 m2/g and 0.17 cm3/g). Moreover, N was successfully doped on the surface of biochar, and the N content was up to 4.24 at.% with the majority of basic species such as pyridinic and pyrrolic N. This could be attributed to a large amount of N-containing functional groups and phosphoric acid released gradually at the presence of UP during the heating process. The prepared biochar exhibited good CO2 and H2S adsorption capacities up to 1.34 mmol/g and 54.8 mg/g, respectively, which was much higher than those without UP addition (0.958 mmol/g and 0.24 mg/g). The excellent adsorption properties of CO2 and H2S were tightly related to the improved microporous structure and surface basic N-containing functional groups on the biochar.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2020.119932