Green Energy & Environment (Oct 2023)

Integration of pore structure modulation and B, N co-doping for enhanced capacitance deionization of biomass-derived carbon

  • Yao Qiu,
  • Chunjie Zhang,
  • Rui Zhang,
  • Zhiyuan Liu,
  • Huazeng Yang,
  • Shuai Qi,
  • Yongzhao Hou,
  • Guangwu Wen,
  • Jilei Liu,
  • Dong Wang

Journal volume & issue
Vol. 8, no. 5
pp. 1488 – 1500

Abstract

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Biomass-derived carbon has demonstrated great potentials as advanced electrode for capacitive deionization (CDI), owing to good electroconductivity, easy availability, intrinsic pores/channels. However, conventional simple pyrolysis of biomass always generates inadequate porosity with limited surface area. Moreover, biomass-derived carbon also suffers from poor wettability and single physical adsorption of ions, resulting in limited desalination performance. Herein, pore structure optimization and element co-doping are integrated on banana peels (BP)-derived carbon to construct hierarchically porous and B, N co-doped carbon with large ions-accessible surface area. A unique expansion-activation (EA) strategy is proposed to modulate the porosity and specific surface area of carbon. Furthermore, B, N co-doping could increase the ions-accessible sites with improved hydrophilicity, and promote ions adsorption. Benefitting from the synergistic effect of hierarchical porosity and B, N co-doping, the resultant electrode manifest enhanced CDI performance for NaCl with large desalination capacity (29.5 mg g−1), high salt adsorption rate (6.2 mg g−1 min−1), and versatile adsorption ability for other salts. Density functional theory reveals the enhanced deionization mechanism by pore and B, N co-doping. This work proposes a facile EA strategy for pore structure modulation of biomass-derived carbon, and demonstrates great potentials of integrating pore and heteroatoms-doping on constructing high-performance CDI electrode.

Keywords