Abstract
Porphyrin functionalized reduced graphene oxide (rGO) is attractive for multi-disciplinary research studies, and its improvements for an rGO-based field effect transistor (rGO-FET) were exploited to realize ultrasensitive biochemical and clinical assay. Although it was believed that the hybrids of porphyrin and rGO can make positive impacts on the rGO-FET’s electronic performances, the understandings of its functions are still piecemeal. Herein, the reduced mixtures of tetra (4-aminophenyl) porphyrin (TAP), GO (TAP-rGO), and the FET channeled by them are examined to throw a light on the possible approaches through which TAP affects rGO’s quality and its carrier mobilities. A TAP-caused game relationship is established by deliberating about the results of the intentionally altered experimental conditions, including TAP contents and the overmixing pretreatment. The p-type doping deduction for the right-shifted ambipolar transfer characteristic curves is evidenced by X-ray photoelectron spectroscopy (XPS). The problems posed by the TAP-induced FET features’ improvement, regression, and deterioration are clarified by the integrated proofs from Raman fingerprints, the amide and carboxyl groups’ changing trajectory found by C1s XPS core spectra, and the enlarged few-layer graphene morphology from atomic force microscope and transmission electron microscope. We hope that this effort will provide some constructive recommendations for producing low-cost graphene derivatives and promoting their applications in FET-like electronic components.
Highlights
Reduced graphene oxide is one of the welcomed two-dimensional and biofunctional materials for field effect transistor (FET)-type biosensors to fulfill the clinical detections [1,2], due to its balancing talent to recover the destroyed graphene basal plane in graphene oxide (GO) and preserve part of the oxygen-containing groups on it [3]
Speaking, porphyrin-functionalized chemically Reduced graphene oxide (rGO) may provide an inspiring solution for fabricating low-cost and biocompatible FET-type sensors, because of the economical merit inherent in its total liquid process, and the promising biocompatibility [8] and biocatalysis in the oxygen reduction reaction (ORR) [9]
Performance electronic featuresofofFETs the as-prepared tetra (4-aminophenyl) porphyrin (TAP)-rGO-based FETs are examined and presented in Firstly, it isfeatures found of thethe output currentsTAP-rGO-based (IDS ) are alteredFETs withare theexamined addition and of TAP, but thein as-prepared presented changing
Summary
Reduced graphene oxide (rGO) is one of the welcomed two-dimensional and biofunctional materials for field effect transistor (FET)-type biosensors to fulfill the clinical detections [1,2], due to its balancing talent to recover the destroyed graphene basal plane in graphene oxide (GO) and preserve part of the oxygen-containing groups on it [3]. In the nonlinear optical study of a GO and tetra (4-aminophenyl) porphyrin (TAP) hybrid, an electron and/or energy transfer from photoexcited TAP to its covalently linked GO moiety was manifested [12]. Motivated by those fundamental studies, more interesting studies about the physicochemical mechanism between porphyrin and graphene [13], as well as the applications of their hybrids, have been reported. The decorated rGO-based field effect transistor (rGO-FET) by the composite of Fe(III) meso-tetra (4-carboxyphenyl) porphyrin (FeTCP) and rGO (FGPCs) was reported to realize the ultrasensitive
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