Abstract
Composite nanoparticles were synthesized by eco-friendly hydrothermal process and characterized by different spectroscopic techniques. All the spectroscopic techniques suggested the synthesis of well crystalline optically active composite nanoparticles with average diameter of ∼30 nm. The synthesized nanoparticles were applied for the development of chemical sensor which was fabricated by coating the nanoparticles on silver electrode for the recognition of phthalimide using simple I–V technique. The developed sensor exhibited high sensitivity (1.7361 µA.mM−1.cm−2), lower detection limit (8.0 µM) and long range of detection (77.0 µM to 0.38 M). Further the resistances of composite nanoparticles based sensor was found to be 2.7 MΩ which change from 2.7 to 1.7 with change in phthalimide concentration. The major advantages of the designed sensor over existing sensors are its simple technique, low cost, lower detection limit, high sensitivity and long range of detection. It can detect phthalimide even at trace level and sense over wide range of concentrations. Therefore the composite nanoparticals would be a better choice for the fabrication of phthalimide chemical sensor and would be time and cost substituted implement for environmental safety.
Highlights
Environmental pollution has acknowledged substantial consideration in recent times due to detrimental upshot on human health and living beings [1,2,3]
Revealing and scrutinizing of perilous chemicals and dilapidation of organic pollutants are vital for environmental pollution control and industrial purposes
The crystal structure of composite nanoparticles was examined by X-ray powder diffraction and the outcomes are illustrated in
Summary
Environmental pollution has acknowledged substantial consideration in recent times due to detrimental upshot on human health and living beings [1,2,3]. Phthalimide is used in plastics, different chemical synthesis, dyes and fungicide It is toxic material which acts as strong skin, eye and upper respiratory tract irritant. The size, structure and properties of electrode materials determine sensitivity and selectivity of electrochemical sensor [1,10]. The present study is the continuation of our effort for the development of chemical sensor for environmental and medicinal applications [1,10]. In this contribution, growth of composite nanoparticles was carried out by simple low cost method and analyzed by XRD, FESEM, EDS, FTIR, and UV-vis. Sensing element in the devices, which are used for environmental monitoring and industrial applications
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