<p>To address the challenging issue of the co-existence of inorganic heavy metals and organic pollutants in wastewater, this study proposes a “waste-to-catalyst” strategy. In it, a novel carbon nitride (CN)/Cd(OH)<sub>2</sub> nanocomposite was prepared by immobilizing toxic heavy metal ions (using Cd<sup>2+</sup> as a model) from water onto CN via a simple stirring process, effectively converting them into active components of the CN nanocomposite. This nanocomposite exhibited outstanding dual functionality: it not only achieved highly efficient degradation of the malachite green (MG) dye (98.58% removal within 40&#xa0;min), with its performance significantly outperforming some comparative samples, but also effectively converting trace Cd<sup>2+</sup> into surface-active components of CN nanocomposite. This demonstrates a “waste-to-catalyst” approach for enhancing photocatalytic performance by loading trace heavy metal. This dual functionality was visually confirmed by a phytotoxicity test using soybean growth as a marker: after treatment with CN/Cd(OH)<sub>2</sub>, the inhibition of soybean growth caused by MG and Cd<sup>2+</sup> in the wastewater can be effectively eliminated. The increased charge separation and broadened light absorption are the main reasons for its high performance. This research offers a viable new strategy for the synergistic remediation of complex wastewater contaminated with both organic dyes and heavy metals.</p>

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Synergistic Photocatalytic Degradation of Organic Dyes and Immobilization of Heavy Metals by in Situ Conversion of Cd2+ into an Active Component on Carbon Nitride

  • Zehang Zheng,
  • Shan Li,
  • Zhekai Huang,
  • Lixia Qin,
  • Taiyang Zhang,
  • Shi-Zhao Kang,
  • Xiangqing Li

摘要

To address the challenging issue of the co-existence of inorganic heavy metals and organic pollutants in wastewater, this study proposes a “waste-to-catalyst” strategy. In it, a novel carbon nitride (CN)/Cd(OH)2 nanocomposite was prepared by immobilizing toxic heavy metal ions (using Cd2+ as a model) from water onto CN via a simple stirring process, effectively converting them into active components of the CN nanocomposite. This nanocomposite exhibited outstanding dual functionality: it not only achieved highly efficient degradation of the malachite green (MG) dye (98.58% removal within 40 min), with its performance significantly outperforming some comparative samples, but also effectively converting trace Cd2+ into surface-active components of CN nanocomposite. This demonstrates a “waste-to-catalyst” approach for enhancing photocatalytic performance by loading trace heavy metal. This dual functionality was visually confirmed by a phytotoxicity test using soybean growth as a marker: after treatment with CN/Cd(OH)2, the inhibition of soybean growth caused by MG and Cd2+ in the wastewater can be effectively eliminated. The increased charge separation and broadened light absorption are the main reasons for its high performance. This research offers a viable new strategy for the synergistic remediation of complex wastewater contaminated with both organic dyes and heavy metals.