A LOW-COST COLORIMETRIC DETECTION OF HG2+ USING PAPER-BASED SENSOR WITH EUCLIDEAN DISTANCE APPROACH

Authors

  • Muh. Supwatul Hakim Universitas Palangka Raya
  • Tety Wahyuningsih Manurung Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Palangka Raya, Central Kalimantan, Palangka Raya, 73111, Indonesia
  • Mokhamat Ariefin Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Palangka Raya, Central Kalimantan, Palangka Raya, 73111, Indonesia
  • Dwi Hermayantiningsih Department of Chemistry, Faculty of Mathematics and Natural Sciences, Universitas Palangka Raya, Central Kalimantan, Palangka Raya, 73111, Indonesia

DOI:

https://doi.org/10.36526/jc.v8i1.7434

Keywords:

mercury, paper-based sensor, colorimetry

Abstract

Mercury (Hg) is a highly toxic heavy metal that poses significant risks to human health and aquatic ecosystems. The development of rapid and low-cost detection methods is urgently needed. In this work, the paper-based colorimetric sensor was developed by immobilizing dithizone onto Whatman No. 41 filter paper for the detection of Hg2+. The sensor utilized the color change of the sensor from green to orange with the color formation of Hg–dithizone complex. FTIR analysis confirmed the successful immobilization of dithizone with characteristic absorption of C=N and C=S vibrations. For quantification, digital images captured by a smartphone were analyzed using the Euclidean Distance (ED) approach. The sensor demonstrated a linear response in the concentration range of 1–5 mg/L (R2 = 0.991), with a limit of detection (LOD) and limit of quantification (LOQ) of 0.50 mg/L and 1.67 mg/L, respectively. Furthermore, the sensor exhibited high precision with a %RSD of 4.39%. Selectivity tests under acidic conditions confirmed that Hg2+ yielded the highest ED value compared to other metal ions such as Cu2+, Pb2+, Co2+, Ni2+, and Zn2+. This paper-based sensor provides a simple, portable, and cost-effective tool for the on-site monitoring of mercury in environmental samples

References

Akesa, K. V., Julizar, J., & Kadri, H. (2018). Identifikasi Kadar Merkuri pada Depot Air Minum Isi Ulang di Kelurahan Jati Kota Padang. Jurnal Kesehatan Andalas, 7(3), 347–351.

Attaallah, R., & Amine, A. (2022). Highly selective and sensitive detection of cadmium ions by horseradish peroxidase enzyme inhibition using a colorimetric microplate reader and smartphone paper-based analytical device. Microchemical Journal, 172, 1–8.

Chen, Y., et al. (2026). Revealing the formation of nanoparticulate mercury sulfide in Hg (II)-DOM-Sulfide(-II) systems with nanomolar Hg (II) by using liquid chromatography-ICP-MS analysis. Journal of Environmental Sciences, 161, 445–453.

Chen, Z., Zhang, Z., Qi, J., You, J., Ma, J., & Chen, L. (2023). Colorimetric detection of heavy metal ions with various chromogenic materials: Strategies and applications. Journal of Hazardous Materials, 441, 129889.

da Silva Cunha, F. A., de Oliveira, M. J., Florez-Rodriguez, P. P., & Santos, J. C. C. (2022). Mercury speciation in estuarine water using dithiol-based magnetic solid-phase extraction and cold vapor atomic fluorescence spectrometry. Spectrochimica Acta Part B: Atomic Spectroscopy, 192, 1–9.

Friedrich, H. K. J., Michalke, B., Karst, U., & Michaelis, V. (2024). Using L-cysteine to enhance calibration range and prevent a memory effect in mercury analysis of complex samples via ICP-OES. Journal of Trace Elements in Medicine and Biology, 84, 127467.

Ganesh, A., Aruchamy, G., Park, K., & Kim, B.-K. (2025). One-step process for ultrasensitive detection of mercuric ions using nanoparticle formation and single-entity electrochemistry. Sensors and Actuators B: Chemical, 431, 137412.

Hakim, M. S., & Bilad, M. R. (2024). Colorimetric Sensor for Heavy Metal Ions Detection: A Short Review. EVERGREEN Joint Journal of Novel Carbon Resource Sciences & Green Asia Strategy, 11(04), 3127–3142.

Hakim, M. S., Hermayantiningsih, D., Wahyuningsih Manurung, T., Ariefin, M., & Roil Bilad, M. (2025). Recent Progress on Colorimetric Sensor for Hg (II) Detection. Jurnal Sains Materi Indonesia, 27(1), 1–10.

Hospodarova, V., Singovszka, E., & Stevulova, N. (2018). Characterization of Cellulosic Fibers by FTIR Spectroscopy for Their Further Implementation to Building Materials. American Journal of Analytical Chemistry, 09(06), 303–310.

Juliana, P. S., Kurniaty, N., & Miftah, A. M. (2016). Pengembangan Metode Deteksi Timbal dan Merkuri Pencemar Pangan Berdasarkan Pembentukan Senyawa Kompleks Berwarna. Prosiding Farmasi, 2(2), 488–495.

Khan, H., Ahmed, M. J., & Bhanger, M. I. (2005). A simple spectrophotometric determination of trace level mercury using 1,5-diphenylthiocarbazone solubilized in micelle. Analytical Sciences, 21(5), 507–512.

Lins, S. S., Virgens, C. F., dos Santos, W. N. L., Estevam, I. H. S., Brandão, G. C., Felix, C. S. A., & Ferreira, S. L. C. (2019). On-line solid phase extraction system using an ion imprinted polymer based on dithizone chelating for selective preconcentration and determination of mercury (II) in natural waters by CV AFS. Microchemical Journal, 150, 104075.

Neera, C., Nidhi, S., & Ureena, J. (2020). A review article on analytical method validation. Journal Pharma Innovation, 1(1), 45–58.

Nshnsh, K. M., Cavoura, O., Davidson, C. M., & Gibson, L. T. (2023). Low-cost colorimetric mercury sensor based on immobilisation of rhodamine B thiolactone in a sustainable agar-agar gel substrate. Microchemical Journal, 195, 109481.

Nur, Y., Rohaeti, E., & Darusman, L. K. (2017). Optical sensor for the determination of Pb2+ based on immobilization of dithizone onto Chitosan-Silica membrane. Indonesian Journal of Chemistry, 17(1), 7–14.

Preechaburana, P., Sangnuy, S., & Amloy, S. (2023). Paper-based colorimetric sensor for mercury ion detection using smartphone digital imaging. Journal of Metals, Materials and Minerals, 33(2), 81–87.

Rong, R., Cai, Z., Li, X., & Wang, Z. (2022). Ultra-sensitive determination of mercury by atmospheric pressure glow discharge atomic emission spectrometry coupled with cold vapor generation. Journal of Analytical Atomic Spectrometry, 37(11), 2377–2382.

Shrivas, K., Monisha, Kant, T., Karbhal, I., Kurrey, R., Sahu, B., … Pervez, S. (2020). Smartphone coupled with paper-based chemical sensor for on-site determination of iron (III) in environmental and biological samples. Analytical and Bioanalytical Chemistry, 412(7), 1573–1583.

Yan, Z., Yuen, M. F., Hu, L., Sun, P., & Lee, C. S. (2014). Advances for the colorimetric detection of Hg2+ in aqueous solution. RSC Advances, 4(89), 48373–48388.

Zaetun, S., Dewi, L. B. K., Sutami, N. L. P. S., & Srigede, L. (2015). Gambaran Kadar Merkuri (Hg) dengan Pemberian Tanaman Eceng Gondok (Echorina crassipes) menggunakan Metode Spektrofotometer UV-Vis. Jurnal Riset Kesehatan, 4(1), 700–707.

Zargoosh, K., & Farhadian Babadi, F. (2015). Highly selective and sensitive optical sensor for determination of Pb 2+ and Hg2+ ions based on the covalent immobilization of dithizone on agarose membrane. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 137, 105–110.

Downloads

Published

2026-03-31

How to Cite

Hakim, M. S., Wahyuningsih Manurung, T., Ariefin, M., & Hermayantiningsih, D. (2026). A LOW-COST COLORIMETRIC DETECTION OF HG2+ USING PAPER-BASED SENSOR WITH EUCLIDEAN DISTANCE APPROACH. Jurnal Crystal : Publikasi Penelitian Kimia Dan Terapannya, 8(1), 184–190. https://doi.org/10.36526/jc.v8i1.7434

Issue

Vol. 8 No. 1 (2026): Literasi Artikel Penelitian Kimia

Section

Articles

License

Copyright (c) 2026 Muh. Supwatul Hakim, Tety Wahyuningsih Manurung, Mokhamat Ariefin, Dwi Hermayantiningsih

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

 

Creative Commons License Creative Commons Attribution-4.0 International License