Detection of cyanide ion in aqueous medium using an azo dye containing phenanthroimidazole

Zahra Zamiraei ¹ ( Department of Chemistry, University Campus, University of Guilan, Rasht, Iran )
Kurosh Rad Moghadam ² ( Department of Chemistry, Faculty of Sciences, University of Guilan, Rasht, Iran )

Submited date : 2025-05-11 Accepted date : 2025-08-10

Keywords: Azo dyes, Phenanthroimidazole, Cyanide ion, Optical chemosensor, Environmental toxicity,

Abstract :

In this study, the synthesis and application of a novel azo dye containing a phenanthro[10,9-d] imidazole group as a chemosensor for cyanide ions (CN⁻) in aqueous media were investigated. Due to its high toxicity and detrimental effects on human health and natural ecosystems, cyanide requires rapid, sensitive, and selective detection methods. The synthesized dye exhibited high selectivity and sensitivity toward CN⁻ via an optical absorption mechanism accompanied by a distinct color change, enabling effective detection even in the presence of competing anions. Spectroscopic analysis revealed a detection limit of 5 × 10⁻⁶ M based on absorption spectral analysis, while the visual detection limit using test strips was found to be 2 × 10⁻⁵ M. A noticeable color transition from pale yellow to orange, along with a red shift in the UV-Vis spectrum, indicated the formation of a stable complex between the dye and the cyanide ion. To improve the practical applicability of this method, test strips were fabricated by immobilizing the synthesized dye, allowing for rapid and visual detection of CN⁻ in real samples (such as industrial wastewater and effluents) without the need for complex instrumentation. Owing to its simplicity, low cost, high sensitivity, and excellent selectivity, the proposed method shows great potential for environmental monitoring, industrial applications, and water quality assessment.

References:

 Alvillo-Rivera, A., Garrido-Hoyos, S., Buitrón, G., Thangarasu-Sarasvathi, P., & Rosano-Ortega, G. (2021). Biological treatment for the degradation of cyanide: A review. Journal of Materials Research and Technology, 12, 1418-1433.
 Baud, F. J. (2007). Cyanide: critical issues in diagnosis and treatment. Human & experimental toxicology, 26(3), 191-201.
 Chakraborty, S., Paul, S., Roy, P., & Rayalu, S. (2021). Detection of cyanide ion by chemosensing and fluorosensing technology. Inorganic Chemistry Communications, 128, 108562.
 Dash, R. R., Gaur, A., & Balomajumder, C. (2009). Cyanide in industrial wastewaters and its removal: a review on biotreatment. Journal of hazardous materials, 163(1), 1-11.
 Doyle, M. P., McKervey, M. A., & Ye, T. (1998). Modern catalytic methods for organic synthesis with diazo compounds: from cyclopropanes to ylides. John Wiley & Sons.
 Gul, Z., Khan, S., Ullah, S., Ullah, H., Khan, M. U., Ullah, M., & Altaf, A. A. (2024). Recent development in coordination compounds as a sensor for cyanide ions in biological and environmental segments. Critical Reviews in Analytical Chemistry, 54(3), 508-528..
 Hendry-Hofer, T. B., Ng, P. C., Witeof, A. E., Mahon, S. B., Brenner, M., Boss, G. R., & Bebarta, V. S. (2019). A review on ingested cyanide: risks, clinical presentation, diagnostics, and treatment challenges. Journal of medical toxicology, 15, 128-133.
 Jaszczak, E., Polkowska, Ż., Narkowicz, S., & Namieśnik, J. (2017). Cyanides in the environment—analysis—problems and challenges. Environmental Science and Pollution Research, 24, 15929-15948.
 Kathiravan, A., Sengottiyan, S., Puzyn, T., Gopinath, P., Ramasubramanian, K., Susila, P. A., & Jhonsi, M. A. (2022). Rapid colorimetric discrimination of cyanide ions–mechanistic insights and applications. Analytical Methods, 14(5), 518-525.
 Kuyucak, N., & Akcil, A. (2013). Cyanide and removal options from effluents in gold mining and metallurgical processes. Minerals Engineering, 50, 13-29.
 March, J. (2007). March’s advanced organic chemistry. John Wiley & Sons.
 Panja, S., Panja, A., & Ghosh, K. (2021). Supramolecular gels in cyanide sensing: A review. Materials Chemistry Frontiers, 5(2), 584-602.
 Vogiazi, V., De La Cruz, A., Mishra, S., Shanov, V., Heineman, W. R., & Dionysiou, D. D. (2019). A comprehensive review: Development of electrochemical biosensors for detection of cyanotoxins in freshwater. ACS sensors, 4(5), 1151-1173.
 Wen, J., Zhao, W., Gao, X., Ren, X., Dong, C., Wang, C., ... & Li, J. (2022). Synthesis of [1, 2, 3] triazolo-[1, 5-a] quinoxalin-4 (5 H)-ones through photoredox-catalyzed [3+ 2] cyclization reactions with hypervalent iodine (III) reagents. The Journal of Organic Chemistry, 87(6), 4415-4423.
 Zollinger, H. (2003). Color chemistry: syntheses, properties, and applications of organic dyes and pigments. John Wiley & Sons.