D-π-A based Diaminomalenonitrile Imine Compounds as Sensors: From Ion Recognition to Logic Arithmetic Applications

Q4 Chemistry

Asian Journal of Chemistry Pub Date : 2024-07-25 DOI:10.14233/ajchem.2024.31914

Wasseem Akbar, Bashir Ahmed, E. G. Naz, Purvee Bhardwaj, Imtiaz Ahmad Shah, M. A. Kaloo

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Abstract

In this review article, exciting highlights on highly π-conjugated (π-D-A) 2,3-diaminomaleonitrile (DAMN) based imines or Schiff base chemosensors have been reviewed and discussed. Owing to the typical free -NH2 anion recognition site and 1,2-ethylenediamine based chelating structure, both anion and cation sensing has been achieved with such designed molecules. It has been found that ion interactions strongly alter the electronic push-pull and hence intramolecular charge transfer (ICT) properties across the molecular system. So far such molecular recognition strategy has successfully detected ions like F–, CN– and Cu+2 in aqueous as well as non-aqueous media. Importantly, recognition is usually reversible and changes are clearly perceived through naked eyes. In this work, various sensing aspects like mechanism of interaction, type of recognition, sensitivity, reversibility, binding constants and spectral changes (absorption and emission) have been thoroughly discussed. Herein, the designed and fabricated sensor reports have been arranged in systematic order since 2010 so that the reader gets complete and trending picture of how the developments have taken place in the area of this research. In last, essential shortcomings and future challenges existing with the current approaches have also been highlighted.

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作为传感器的基于 D-π-A 的二氨基丙烯腈亚胺化合物：从离子识别到逻辑运算应用

在这篇综述文章中，我们回顾并讨论了高度π-共轭（π-D-A）的 2,3-二氨基马来腈（DAMN）亚胺或希夫碱化学传感器的精彩亮点。由于这种设计的分子具有典型的游离 -NH2 阴离子识别位点和基于 1,2- 乙二胺的螯合结构，因此可以实现阴离子和阳离子传感。研究发现，离子间的相互作用会强烈改变整个分子体系的电子推拉效应，从而改变分子内电荷转移（ICT）特性。迄今为止，这种分子识别策略已成功检测到水介质和非水介质中的 F-、CN- 和 Cu+2 等离子。重要的是，识别通常是可逆的，而且可以通过肉眼清楚地感知变化。在这项工作中，我们深入讨论了各种传感方面的问题，如相互作用机制、识别类型、灵敏度、可逆性、结合常数和光谱变化（吸收和发射）。其中，自 2010 年以来设计和制造的传感器报告按系统顺序排列，以便读者全面了解该研究领域的发展动态。最后，还强调了当前方法存在的主要不足和未来的挑战。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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