Abstract
In this work, the effect of fluorine and chlorine substituents in tetrasubstituted zinc phthalocyanines, introduced into the non-peripheral (ZnPcR4-np, R = F, Cl) and peripheral (ZnPcR4-p, R = F, Cl) positions of macrocycle, on their structure and chemiresistive sensor response to low concentration of ammonia is studied. The structure and morphology of the zinc phthalocyanines films (ZnPcR4) were investigated by X-ray diffraction and atomic force microscopy methods. To understand different effects of chlorine and fluorine substituents, the strength and nature of the bonding of ammonia and ZnPcHal4 molecules were studied by quantum chemical simulation. It was shown on the basis of comparative analysis that the sensor response to ammonia was found to increase in the order ZnPcCl4-np < ZnPcF4-np < ZnPcF4-p < ZnPcCl4-p, which is in good agreement with the values of bonding energy between hydrogen atoms of NH3 and halogen substituents in the phthalocyanine rings. ZnPcCl4-p films demonstrate the maximal sensor response to ammonia with the calculated detection limit of 0.01 ppm; however, they are more sensitive to humidity than ZnPcF4-p films. It was shown that both ZnPcF4-p and ZnPcCl4-p and can be used for the selective detection of NH3 in the presence of carbon dioxide, dichloromethane, acetone, toluene, and ethanol.
Highlights
Ammonia is a highly irritating gas with a pungent smell
The structure and morphology of their films deposited by thermal evaporation in vacuum were investigated by X-ray diffraction (XRD) and atomic force microscopy methods
It was shown that both position and type of substituents affect the structure of single crystals and films of zinc phthalocyanines
Summary
Ammonia is a highly irritating gas with a pungent smell. The problem of detecting ammonia is important in various sectors of agriculture and industry related to the production and use of fertilizers, as well as refrigeration systems [1]. Chemiresistive gas sensors have attracted considerable attention in the field of sensor technology due to their advantages such as simplicity, low cost, and miniaturization capability [4,16]. Metal phthalocyanines (MPc) attract noticeable interest for sensing applications [18,19,20] due to their high sensitivity to different analytes, exceptional stability, versatile chemical system, and excellent processability resulting in the manufacture of thin films. Their properties can be tuned by introducing desirable
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