Conducting polymers are being widely employed in the manufacture of nanostructured sensors due to breakthroughs in the development of sophisticated nano-sized forms. One of the most attractive conducting polymers is polyaniline (PANI) due to its interesting electrical, electrochemical and optical properties, such as air stability and simple acid/base doping/dedoping chemistry. However, the fact that aniline is a carcinogenic monomer, its insolubility in common solvents and the acidic conditions required to the most conductive form of PANI are made its commercial application very difficult so far. The synthesis of PANI nanoparticles using dodecylbenzenesulphonic acid (DBSA) as both dopant and surfactant have allowed the use of this polymer in aqueous media, improving its processability. The additional use of ammonium persulphate (APS) as an oxidant together with DBSA during chemical PANI polymerization have led to the creation of a spherical PANI nanoparticle aqueous dispersion. Such dispersion can be deposited onto the electrodes by means of traditional methods, such as drop coating, or using more sophisticated techniques, such as inkjet printing. The application of PANI nanoparticles inkjet printed onto carbon paste screen-printed electrodes for ascorbic acid sensing is shown in the present wor

Gonzalez-Macia, Laura

Killard, Anthony J.

Morrin, Aoife

Smyth, Malcolm R.

Name not available

Polyaniline Nanoparticles for Sensing ApplicationsIntroductionConducting polymers are being widely employed in the manufacture of nanostructured sensors due to breakthroughs in the development ofsophisticated nano-sized forms. One of the most attractive conducting polymers is polyaniline (PANI) due to its interesting electrical,electrochemical and optical properties, such as air stability and simple acid/base doping/dedoping chemistry. However, the fact that aniline is acarcinogenic monomer, its insolubility in common solvents and the acidic conditions required to the most conductive form of PANI are made itscommercial application very difficult so far. The synthesis of PANI nanoparticles using dodecylbenzenesulphonic acid (DBSA) as both dopant andsurfactant have allowed the use of this polymer in aqueous media, improving its processability. The additional use of ammonium persulphate (APS)as an oxidant together with DBSA during chemical PANI polymerization have led to the creation of a spherical PANI nanoparticle aqueousdispersion. Such dispersion can be deposited onto the electrodes by means of traditional methods, such as drop coating, or using moresophisticated techniques, such as inkjet printing.The application of PANI nanoparticles inkjet printed onto carbon paste screen-printed electrodes for ascorbic acid sensing is shown in the presentwork.Laura Gonzalez-Macia, Aoife Morrin, Malcolm R. Smyth, Anthony J. Killard*Sensors and Separations Group, National Centre for Sensor Research, School of Chemical Sciences, Dublin City University, Dublin 9 *email address: tony.killard@dcu.ieInkjet printing as a Deposition ToolCarbon-paste screen-printed electrodes werefabricated in-house and were used as electrodeplatforms for depositing PANI nanoparticles. PANIInkjet Printed PANI for Ascorbic Acid SensingInkjet printing is a non-contact printing methodthat allows us to pattern our conductingpolymers onto different substrates in a low-costand high precision way. In this work, apiezoelectric drop-on-demand inkjet printer wasused to deposit our PANI nanoparticle ink. Inthis device, deformation of the piezoceramicmaterial confined in the printhead increase thepressure inside the nozzles, causing the ejectionof an ink drop through the orifice, .At pH=6.8 (experimental conditions) , ascorbic acid is present as ascorbate. The oxidation of L-ascorbate to dehydro-L-ascorbic acid is a two electron transfer process that is enhanced in thepresence of PANI. At neutral pH, polyaniline exists as the emeraldine salt. Two oxidizedpolyaniline monomers (2PANI+) react with L-ascorbic acid, carrying out the oxidation of theascorbate to dehydro-L-ascorbic acid whereas reduced PANI (2PANI0) is reoxidized at theelectrodeCharacterization of PANI NanoparticlesPANI nanoparticles were synthesized by the rapid mixing method. The use of DBSA as dopantduring the polymerization induces a spherical nanoparticulate growth, leading to a inkjetprintable PANI-DBSA nanodispersion. The size of the resulting nanoparticles is a key factor forits later use as an inkjet printable material. Typical inkjet nozzle size is ~20-30µm, whichmeans that PANI must be a stable nanodispersion to avoid the nozzle orifice blocking.Visualization of PANI nanoparticles usingNANOSIGHT system. This technique allowsthe real time visualization of nanoscaleparticles in liquids as well as nanoparticlessizing. The system comprises a metallisedoptical element illuminated by laser beam atthe surface of which nanoscale particles insuspension (500µl) can be directly visualizedusing only a conventional optical microscope.The program analyses the paths that theparticles take under Brownian motion over asuitable period of time (10-20s) in order tocalculate nanoparticle size. For PANIaqueous nanodispersion, PANI size is about75nm.was inkjet printed using a Commercial ResearchFuji Dimatix printer.Inkjet printing was found to be an ideal deposition tool for the polyaniline dispersions, given its stability and nanoparticulate nature in an aqueous system. The particle size in solution was found to be of about 75 nm using the NANOSIGHT system making it suitable for piezoelectric inkjet printing. Inkjet printed PANI films on carbon-paste electrodes resulted in an excellent platform for ascorbic acid sensing, where 20 printed layers of polymer was found to be optimal. The application of this sensor for measuring ascorbic acid in oranges was demonstrated. Amperometric curve (left) at 0 V vs Ag/AgCl for 600 s in PBS pH=6.8. Catalytic response ofan inkjet printed PANI-modified electrode (20 layers) when ascorbic acid was added tosolution (1 - 5 mM). Calibration curve (right) for ascorbic acid sensing. The data correspondsto the previous modified electrode measured in PBS pH=6.8, when ascorbic acid (1 – 5 mM)was added.Optimization of the number of inkjet printed PANI layers(i.e., film thickness). Standard procedure was carried outusing electrodes inkjet printed with a range of PANI layers(0 - 40). The analysis of the catalytic responses when[ascorbic acid] in solution was 5 mM was carried out. Thedependence of the response on the number of inkjetprinted PANI layers is shown in the graph (right). It can beobserved that the catalytic response increased as thenumber of PANI layers was increased up to an optimum of20 layers Increasing the number of layers of PANI beyond20 did not result in higher responses.Measurement of ascorbic acid in fresh orangesAmperometric curve at 0 V vs Ag/AgCl for 600 s in PBS(pH = 6.8). Catalytic response of a inkjet printed PANIfilm (20 layers) when juice from an orange was added tothe solution (100 - 500 µl). Using a standard calibrationcurve, the concentration of ascorbic acid found in thenatural orange juice was 0.32 mM.Characterization of Inkjet Printed PANI FilmsScanning Electron Microscopy images obtained on a bare carbon-paste screen-printedelectrode (left) and an PANI film inkjet printed (20 layers) on top of the carbon-paste electrode.A rough, nodular surface can be observed on the bare carbon paste due to the particulatenature of the paste. In contrast, a smooth surface was observed for the PANI-modified carbonpaste, due to the infill of the carbon structure by the PANI nanoparticles.Number of PANI layers0 10 20 30 40i / A2.0e-64.0e-66.0e-68.0e-61.0e-51.2e-51.4e-5

Polyaniline nanoparticles for sensing applications.

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Polyaniline nanoparticles for sensing applications.

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