Naglaa M. Nooredeen scite author profile

International audienceIn this work, we report the development of a highly sensitive capacitance chemical sensor based on a copper C, C, C, C-tetra-carboxylic phthalocyanine-acrylate polymer adduct (Cu(II) TCPc-PAA) for phosphate ions detection. A capacitance silicon nitride substrate based Al-Cu/Si-p/SiO2/Si3N4 structure was used as transducer. These materials have provided good stability of electrochemical measurements. The functionalized silicon-based transducers with a Cu(II) Pc-PAA membrane were characterized by using Mott-Schottky technique measurements at different frequency ranges and for different phosphate concentrations. The morphological surface of the Cu(II) Pc-PAA modified silicon-nitride based transducer was characterized by contact angle measurements and atomic force microscopy. The pH effect was also investigated by the Mott-Schottcky technique for different Tris-HCl buffer solutions. The sensitivity of silicon nitride was studied at different pH of Tris-HCl buffer solutions. This pH test has provided a sensitivity value of 51 mV/decade. The developed chemical sensor showed a good performance for phosphate ions detection within the range of 10(-10) to 10(-5) M with a Nernstian sensitivity of 27.7 mV/decade. The limit of detection of phosphate ions was determined at 1 nM. This chemical sensor was highly specific for phosphate ions when compared to other interfering ions as chloride, sulfate, carbonate and perchlorate. The present capacitive chemical sensor is thus very promising for sensitive and rapid detection of phosphate in environmental applications

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Novel Sensitive Impedimetric Microsensor for Phosphate Detection Based on a Novel Copper Phthalocyanine Derivative

Fredj

Nooredeen

Azzouzi

et al. 2017

Analytical Letters

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Selective phosphate sensing using copper monoamino-phthalocyanine functionalized acrylate polymer-based solid-state electrode for FIA of environmental waters

Abbas

Radwan

Nooredeen

et al. 2016

J Solid State Electrochem

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A Highly Sensitive Miniaturized Impedimetric Perchlorate Chemical Sensor

Messaoud¹,

Baraket

Dridi³

et al. 2018

IEEE Sensors J.

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Graphene oxide with covalently attached zinc monoamino-phthalocyanine coated graphite electrode as a potentiometric platform for citrate sensing in pharmaceutical preparations

Nooredeen

El‐Ghaffar

Darwish

et al. 2015

J Solid State Electrochem

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A citrate selective coated graphite electrode (CGE) based on zinc monoamino-phthalocyanine functionalized graphene (ZnMAPc-G) has been developed and potentiometrically evaluated. The composition of the membrane prepared from ZnMAPc-G, DOS, and PVC in THF was optimized. The sensor based on ZnMAPc-G containing 5 % ZnMAPc possessed the optimum performance in glycine buffer 0.01 M of pH 3.9 with a near Nernstian slope of −57.3±0.5 mV/decade, a linear range of 8×10 −7 -1×10 −2 mol L −1 and a detection limit of 5×10 −7 mol L −1 . Different electrodes prepared using ZnMAPc as free ionophore or as composite with graphene (ZnMAPc/G) were also evaluated and compared to the electrode containing covalently attached ionophore (ZnMAPc-G). The proposed sensor possessed a long-life of about 6 months without notable drift in its slope and was utilized in the determination of the citrate concentration in some pharmaceutical formulation.

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