<p>The sulfide ion (S<sup>2−</sup>) is one of the toxic pollutants in water systems and its concentration is a critical environmental index. Traditional methods for S<sup>2−</sup> detection&#xa0;are typically confined to laboratory analysis, limiting their applicability for on-site monitoring. Therefore, a chemical vapor generation (CVG)-smartphone colorimetric method was established for S<sup>2−</sup> on-site detection. S<sup>2−</sup> was converted into volatile H<sub>2</sub>S through the CVG process, enabling efficient sample introduction while minimizing interference from complex matrices. The generated H<sub>2</sub>S reacts with Ag-metal-organic framework (Ag-BDC)-immobilized test paper, forming Ag<sub>2</sub>S on its surface and resulting in gradual fluorescence quenching, thereby allowing quantitative detection of S<sup>2−</sup>. The method was successfully applied to the analysis of S<sup>2−</sup> in four real water samples, three condiments and one certified reference water sample, achieving satisfactory recoveries ranging from 98 to 108%. By integrating the advantages of CVG (e.g., high sample introduction efficiency and reduced matrix interference) with those of colorimetry (e.g., operational simplicity and low cost), this approach demonstrates promising potential for rapid and on-site analysis.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Toward on-site analysis: a paper-based luminescent metal organic framework sensing strategy for sulfide via chemical vapor generation-colorimetric system

  • Shichao Li,
  • Yuanyuan He,
  • Jihong Chen,
  • Fengzhou Xu,
  • Zhirong Zou

摘要

The sulfide ion (S2−) is one of the toxic pollutants in water systems and its concentration is a critical environmental index. Traditional methods for S2− detection are typically confined to laboratory analysis, limiting their applicability for on-site monitoring. Therefore, a chemical vapor generation (CVG)-smartphone colorimetric method was established for S2− on-site detection. S2− was converted into volatile H2S through the CVG process, enabling efficient sample introduction while minimizing interference from complex matrices. The generated H2S reacts with Ag-metal-organic framework (Ag-BDC)-immobilized test paper, forming Ag2S on its surface and resulting in gradual fluorescence quenching, thereby allowing quantitative detection of S2−. The method was successfully applied to the analysis of S2− in four real water samples, three condiments and one certified reference water sample, achieving satisfactory recoveries ranging from 98 to 108%. By integrating the advantages of CVG (e.g., high sample introduction efficiency and reduced matrix interference) with those of colorimetry (e.g., operational simplicity and low cost), this approach demonstrates promising potential for rapid and on-site analysis.