Comparative chemical sensor for detection of chromium (VI) in aqueous solution

Sura H. Al-Rekabi; A. A. Alwahib

doi:10.1007/s11801-025-3273-z

Optoelectronics Letters ›› 2025, Vol. 21 ›› Issue (1) : 21 -27. DOI: 10.1007/s11801-025-3273-z

Article

Comparative chemical sensor for detection of chromium (VI) in aqueous solution

Sura H. Al-Rekabi ¹^,^a
, A. A. Alwahib ²

Author information +

History +

PDF

Abstract

A process for purifying aqueous solutions containing heavy and toxic metals such as chromium (Cr) has been investigated. One of the extremely harmful pollutants in rivers and seawater is the heavy metal ions due to their direct impacts on human, animals and plants are hexavalent Cr (VI). Consequently, highly sensitive sensor to detect Cr is essential. Surface plasmon resonance (SPR) technique has attracted huge research interest in detecting heavy metals specifically. In this study, three types of prism-based SPR sensor, gold (Au)/silver (Ag), Au/polyaniline (PANI) and Au/titanium dioxide (TiO₂) nanostructured films, are investigated as potential sensing material to detect the presence of Cr (VI) ions in water. The base Au layer with thickness of 48.3 nm is deposited on a glass slide for all sensors. For Au/Ag, Au/PANI nanofibers and Au/TiO₂ sensor films, the Cr (VI) concentration is varied from 1 ppm to 15 ppm with sensitivity of 0.270 °ppm⁻¹, 0.082 °ppm⁻¹ and 0.039 °ppm⁻¹, respectively. Based on these results, the Au/PANI nanofibers are the most sensitive to Cr (VI) among the tested sensing materials.

Cite this article

Download citation ▾

Sura H. Al-Rekabi, A. A. Alwahib. Comparative chemical sensor for detection of chromium (VI) in aqueous solution. Optoelectronics Letters, 2025, 21(1): 21-27 DOI:10.1007/s11801-025-3273-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Al-Rekabi S, Kamil Y M, Bakar M A, et al.. Hydrous ferric oxide-magnetite-reduced graphene oxide nanocomposite for optical detection of arsenic using surface plasmon resonance. Optics & laser technology, 2019, 111: 417-423 J]

[2]	Tang Z, Li W, Ke G, et al.. Sulfate attack resistance of sustainable concrete incorporating various industrial solid wastes. Journal of cleaner production, 2019, 218: 810-822 J]

[3]	Dvoynenko O, Lo S L, Chen Y J, et al.. Speciation analysis of Cr (VI) and Cr (III) in water with surface-enhanced Raman spectroscopy. ACS omega, 2021, 6(3): 2052-2059 J]

[4]	TARESH R R, ROUSHANI M, KARAZAN Z M. Selective electrochemical detection of chromium ions in water samples by poly (rutin)/carbon black-chitosan nanocomposite-modified glassy carbon electrode[J]. Journal of applied electrochemistry, 2024: 1–10.

[5]	Fernández-Luqueño F, López-Valdez F, Gamero-Melo P, et al.. Heavy metal pollution in drinking water-a global risk for human health: a review. African journal of environmental science and technology, 2013, 7(7): 567-584 [J]

[6]	Santos A F, Lopes D V, Alvarenga P, et al.. Phosphorus removal from urban wastewater through adsorption using biogenic calcium carbonate. Journal of environmental management, 2024, 351: 119875 J]

[7]	SALIM E T, FAKHRI M A, TARIQ S M, et al. The unclad single-mode fiber-optic sensor simulation for localized surface plasmon resonance sensing based on silver nanoparticles embedded coating[J]. Plasmonics, 2023: 1–13.

[8]	QIN Y, XU Y, JI B, et al. Coaction effect of radiative and non-radiative damping on the lifetime of localized surface plasmon modes in individual gold nanorods[J]. The journal of chemical physics, 2023, 158(10).

[9]	FU R, CHEN X, YAN X, et al. Optical fiber sensors for heavy metal ion sensing[J]. Journal of materials science & technology, 2024.

[10]	Kamaruddin N H, Bakar A A A, Yaacob M H, et al.. Enhancement of chitosan-graphene oxide SPR sensor with a multi-metallic layers of Au-Ag-Au nanostructure for lead (II) ion detection. Applied surface science, 2016, 361: 177-184 J]

[11]	Tao H, Hu T, Yan J, et al.. A comparative study of different reagentless plasmon sensors based on Ag-Au alloy nanoparticles for detection of Hg. Sensors and actuators B: chemical, 2015, 208: 43-49 J]

[12]	Shrivas K, Sahu S, Patra G K, et al.. Localized surface plasmon resonance of silver nanoparticles for sensitive colorimetric detection of chromium in surface water, industrial waste water and vegetable samples. Analytical methods, 2016, 8(9): 2088-2096 J]

[13]	Rajakumar K, Kirupha S D, Sivanesan S, et al.. Effective removal of heavy metal ions using Mn₂O₃ doped polyaniline nanocomposite. Journal of nanoscience and nanotechnology, 2014, 14(4): 2937-2946 J]

[14]	AHMAD R. Polyaniline/ZnO nanocomposite: a novel adsorbent for the removal of Cr (VI) from aqueous solution[J]. Advances in composite materials development, 2019: 1–22.

[15]	Sahu S, Sahu U K, Patel R K. Modified thorium oxide polyaniline core-shell nanocomposite and its application for the efficient removal of Cr (VI). Journal of chemical & engineering data, 2019, 64(3): 1294-1304 J]

[16]	Sharma M, Choudhury D, Hazra S, et al.. Effective removal of metal ions from aqueous solution by mesoporous MnO₂ and TiO₂ monoliths: kinetic and equilibrium modelling. Journal of alloys and compounds, 2017, 720: 221-229 J]

[17]	Ibrahim S, Rahman N, Bakar M A, et al.. Room temperature ammonia sensing using tapered multimode fiber coated with polyaniline nanofibers. Optics express, 2015, 23(3): 2837-2845 J]

[18]	Kandasamy S, Velusamy S, Thirumoorthy P, et al.. Adsorption of chromium ions from aqueous solutions by synthesized nanoparticles. Journal of nanomaterials, 2022, 2022: 1-8 J]

[19]	Karimi-Maleh H, Ayati A, Ghanbari S, et al.. Recent advances in removal techniques of Cr (VI) toxic ion from aqueous solution: a comprehensive review. Journal of molecular liquids, 2021, 329: 115062 J]

[20]	Salinas S, Mosquera N, Yate L, et al.. Surface plasmon resonance nanosensor for the detection of arsenic in water. Sensors & transducers, 2014, 183(12): 97 [J]

[21]	Farooqi Z H, Akram M W, Begum R, et al.. Inorganic nanoparticles for reduction of hexavalent chromium: physicochemical aspects. Journal of hazardous materials, 2021, 402: 123535 J]

[22]	Beygisangchin M, Rashid S A, Shafie S, et al.. Preparations, properties, and applications of polyaniline and polyaniline thin films-a review. Polymers, 2021, 13(12): 2003 J]

[23]	Brungesh K, Nagabhushana B, Harish M, et al.. An efficient removal of toxic Cr (VI) from aqueous solution by MnO₂ coated polyaniline nanofibers: kinetic and thermodynamic study. Journal of analytical toxicology, 2017, 7(2161): 2161-0525 [J]

[24]	Alwahib A, Al-Rekabi S H, Muttlak W H. Comprehensive study of generating sharp dip using numerical analysis in prism based surface plasmon resonance. AIP conference proceedings, 2020, 2213: 020143 J]

[25]	Fazlzadeh M, Rahmani K, Zarei A, et al.. A novel green synthesis of zero valent iron nanoparticles (NZVI) using three plant extracts and their efficient application for removal of Cr (VI) from aqueous solutions. Advanced powder technology, 2017, 28(1): 122-130 J]