0000000000148760

AUTHOR

Yap Wing Fen

showing 3 related works from this author

Structural characterization and optical constants of p-toluene sulfonic acid doped polyaniline and its composites of chitosan and reduced graphene-ox…

2020

Para-Toluene sulfonic acid doped polyaniline (PANI), PANI/chitosan composites, PANI/reduced graphene-oxide composites and a ternary composite comprising of PANI, chitosan and reduced graphene-oxide have synthesised via oxidative polymerisation of aniline by Ammonium peroxydisulfate (APS). FTIR, XRD, FESEM and UV-VIS techniques were performed for the confirmation of the successful synthesis. The fundamental optical parameters such as, complex refractive index, complex dielectric constants and optical conductivity of the PANI and the composites were investigated in the UV-VIS-NIR range. The results show a clear dependence on the constituent component such as sulphur as well as the absorbance …

lcsh:TN1-997SystemMaterials scienceReduced graphene-oxideOxideNanofibersOptical conductivity02 engineering and technologySulfonic acid01 natural sciencesOptical conductivitylaw.invention[SPI.MAT]Engineering Sciences [physics]/MaterialsBiomaterialsAbsorbancechemistry.chemical_compoundFabricationAnilinelawOptical constant0103 physical sciencesFourier transform infrared spectroscopyComposite materialPolymerlcsh:Mining engineering. Metallurgy010302 applied physicschemistry.chemical_classificationChitosanGrapheneMetals and AlloysPolymerTernary compositeDispersion021001 nanoscience & nanotechnologySurfaces Coatings and FilmschemistryCeramics and Composites[PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci]0210 nano-technologyp-Toluene sulfonic acid doped polyanilineRemoval
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Dependence of the Optical Constant Parameters of p-Toluene Sulfonic Acid-Doped Polyaniline and Its Composites on Dispersion Solvents

2020

The optical constants of Para-Toluene sulfonic acid-doped polyaniline (PANI), PANIchitosan composites, PANI-reduced graphene-oxide composites and a ternary composite comprising of PANI, chitosan and reduced graphene-oxide dispersed in diluted p-toluene sulfonic acid (PTSA) solution and N-Methyl-2-Pyrrolidone (NMP) solvent have been evaluated and compared. The optical constant values were extracted from the absorbance spectra of thin layers of the respective samples. The potential utilization of the materials as the active sensing materials of surface plasmon resonance biosensors has also been assessed in terms of the estimated value of the penetration depth through a dielectric medium. The …

Materials scienceoptical constant parametersPharmaceutical Science02 engineering and technologyDielectricSulfonic acid01 natural sciencesOptical conductivityArticleAnalytical Chemistrylcsh:QD241-441chemistry.chemical_compoundlcsh:Organic chemistry0103 physical sciencesDrug DiscoveryPolyanilineDispersion (optics)Physical and Theoretical ChemistryComposite materialPenetration depth010302 applied physicschemistry.chemical_classificationAniline CompoundsOrganic ChemistryBenzenesulfonatesreduced graphene-oxide021001 nanoscience & nanotechnologyPyrrolidinonesSolventchemistryp-toluene sulfonic acid-doped polyanilineChemistry (miscellaneous)Molecular Medicinechitosan0210 nano-technologyRefractive indexsurface plasmon resonance (SPR)Molecules
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Acetone Vapor-Sensing Properties of Chitosan-Polyethylene Glycol Using Surface Plasmon Resonance Technique

2020

To non-invasively monitor and screen for diabetes in patients, there is need to detect low concentration of acetone vapor in the range from 1.8 ppm to 5 ppm, which is the concentration range of acetone vapor in diabetic patients. This work presents an investigation for the utilization of chitosan-polyethylene glycol (PEG)-based surface plasmon resonance (SPR) sensor in the detection of trace concentration acetone vapor in the range of breath acetone in diabetic subjects. The structure, morphology, and elemental composition of the chitosan-PEG sensing layer were characterized using FTIR, UV-VIS, FESEM, EDX, AFM, and XPS methods. Response testing was conducted using low concentration of aceto…

acetone vapor detectionMaterials sciencePolymers and Plasticsnon-invasivesurface plasmon resonance sensor02 engineering and technologyPolyethylene glycol01 natural sciencesArticlelcsh:QD241-441Propanolchemistry.chemical_compoundlcsh:Organic chemistryX-ray photoelectron spectroscopyAcetoneFourier transform infrared spectroscopySurface plasmon resonanceDetection limitdiabetes010401 analytical chemistrytechnology industry and agricultureGeneral Chemistry021001 nanoscience & nanotechnologychitosan-polyethylene glycol film0104 chemical scienceschemistryMethanol0210 nano-technologyNuclear chemistryPolymers
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