Development of a Highly Selective Chloride Ion Potentiometric Sensor Utilizing a Novel N, N-Ethylene-bis-(Salicylideneaminato) Zinc (II) Molecule for Clean Environment

The present study focuses on the advancement of a chloride ion potentiometric sensor that exhibits high selectivity. This sensor employs a novel molecule, namely N, N-Ethylene-bis-(Salicylideneaminato) zinc (II), in order to achieve accurate measurements in the pursuit of maintaining a clean environment. N, N′-Ethylenebis( salicylideneaminato) nickel (II) ionophore has been generated as well as evaluated using analysis of NMR, IR and C, H, N. Subsequently, membranes incorporating the ionophore (I) were developed utilizing poly(vinyl chloride) (PVC) as a matrix, with plasticizing solvent mediators including Dioctyl phthalate (DOP), chloronapthalene (CN), Dibutyl phthalate (DBP), and tri-n-butylphosphate (TBP). Additionally, catalyzed cation discriminator, hexadecyltrimethylammonium bromide (HDTMA) was employed to enhance membrane formation. This sensor performed better than all other variants. Its membrane composition was 5 mg ionophore, 32 mg PVC, 60 mg DBP, and 3 mg HDTMA. Notably, the sensor exhibited an extended operational range of 2.0×10−6 to 1.0×10−1 M, in addition to Nernstian compliance (58.8 mV/Decade) within pH span of 2.3–9.3, and an impressive response time of 19 s. A detection range as low as 1.64×10−6 was attained, indicative of its high sensitivity. Furthermore, the sensor exhibited remarkable selectivity for chloride ions, as confirmed by selectivity coefficient measurements obtained through fixed interference technique (FIM). The sensor demonstrated a satisfactory three-month shelf life and acceptable repeatability. In practical application, the sensor demonstrated effectiveness in quantifying chloride ions in wastewater samples. This work addresses important sustainability issues while contributing to an improved comprehension of the underlying concepts of self-assembled behavior and setting up an option for the generation of efficient sensors with potential uses in photonics and microelectronics.