<p>Cyanide, a silent pillar of modern industry, and its extreme effect on public health and the environment, even at trace levels, necessitate the development of sensors for CN<sup>−</sup> ions. Optical sensors are a better choice for cyanide detection due to their distinct benefits over conventional techniques. Concerning this, a triphenylphosphine-based chemodosimeter, <b>SS1</b>, was designed as a D-π-A system to make it effective to detect CN<sup>−</sup>. The unique, instantaneous and observable colour change of <b>SS1</b> (yellow to lilac) and spectral modifications on contact with CN<sup>−</sup> attesting its selectivity towards CN<sup>−</sup>. The nucleophilic addition is a fact behind the colour and spectral responses of <b>SS1</b> as uncovered from the UV-Vis, <sup>1</sup>H NMR, <sup>13</sup>C NMR, <sup>31</sup>P NMR, and mass spectral analysis. Binding studies reveal a 1:1 stoichiometric ratio between <b>SS1</b> and CN<sup>−</sup>, with a binding constant of 3.31 × 10<sup>4</sup> M<sup>− 1</sup>, indicating strong interaction and efficient cyanide recognition. The far below detection limit (55 nM) of <b>SS1</b> to CN<sup>−</sup> authenticated its sensitivity in real matrices. The Density Functional Theory (DFT)/Time-Dependent Density Functional Theory (TD-DFT) calculations reveal that the added CN<sup>−</sup> triggered the spatial intramolecular charge transfer (ICT) in <b>SS1</b> by conformational alterations through nucleophilic addition, offering a visual colour change, enabling naked eye CN<sup>−</sup> detection. The <b>SS1</b> can be utilized for fingerprint visualization due to its excellent solid-state fluorescence. In addition to that, test buds and real-water analysis were also conducted to assess its real-world applicability, which substantiated the excellent sensing performance of <b>SS1</b> in real-world matrices.</p>

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Spectroscopic and TD-DFT Studies on Colourimetric Detection of Cyanide by a Triphenylphosphine-based Chemodosimeter Via ICT Modulation

  • S. Sridharan,
  • V. Dharaniprabha,
  • P. Ponlakshmi,
  • S. Abirami,
  • M. Manjuladevi,
  • K. Satheshkumar,
  • Kuppanagounder P. Elango

摘要

Cyanide, a silent pillar of modern industry, and its extreme effect on public health and the environment, even at trace levels, necessitate the development of sensors for CN ions. Optical sensors are a better choice for cyanide detection due to their distinct benefits over conventional techniques. Concerning this, a triphenylphosphine-based chemodosimeter, SS1, was designed as a D-π-A system to make it effective to detect CN. The unique, instantaneous and observable colour change of SS1 (yellow to lilac) and spectral modifications on contact with CN attesting its selectivity towards CN. The nucleophilic addition is a fact behind the colour and spectral responses of SS1 as uncovered from the UV-Vis, 1H NMR, 13C NMR, 31P NMR, and mass spectral analysis. Binding studies reveal a 1:1 stoichiometric ratio between SS1 and CN, with a binding constant of 3.31 × 104 M− 1, indicating strong interaction and efficient cyanide recognition. The far below detection limit (55 nM) of SS1 to CN authenticated its sensitivity in real matrices. The Density Functional Theory (DFT)/Time-Dependent Density Functional Theory (TD-DFT) calculations reveal that the added CN triggered the spatial intramolecular charge transfer (ICT) in SS1 by conformational alterations through nucleophilic addition, offering a visual colour change, enabling naked eye CN detection. The SS1 can be utilized for fingerprint visualization due to its excellent solid-state fluorescence. In addition to that, test buds and real-water analysis were also conducted to assess its real-world applicability, which substantiated the excellent sensing performance of SS1 in real-world matrices.