Light-Induced Organic Monolayer Modification of Iodinated Carbon Electrodes

Fairman, Callie; Chockalingam, Muthukumar; Liu, Guozhen; Soeriyadi, Alexander H.; Gooding, J. Justin

doi:10.1021/la403669v

Cited by 9 publications

(9 citation statements)

References 65 publications

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“…In the case of surface modification for traditional carbon substrates, GC and HOPG, various methods have been reported, and diazonium, [31][32][33][34][35] amine, [36][37][38][39][40] azide, [41][42][43][44][45] and olefin [46][47][48][49] derivatives were examined to modify those surfaces. As a systematic study to evaluate the features of modified surfaces using those derivatives has not been reported, we were interested in the difference of those modified surfaces.…”

Section: Surface Modification Of Gc and Hopg With Close-packed Monolayermentioning

confidence: 99%

Fabrication of Biosensing Interface with Monolayers

Tanaka

Niwa

2020

ANAL. SCI.

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Surface modification is recognized as one of fundamental techniques to fabricate biosensing interface, and surface modification of carbon substrate (GC and HOPG) and silica with a close-packed monolayer was especially focused on in this review.In cases of carbon substrate, GC and HOPG, it was demonstrated that surface modification of carbon substrates with diazonium derivatives could afford a close-packed monolayer similar to the self-assembled monolayer (SAM) formation with mercapto derivatives. Similarly, potential of trialkoxysilanes to form a close-packed monolayer was evaluated, and a monolayer modification with a close-packed layer tended to occur under milder condition when the trialkoxysilanes had a longer alkyl chain. In these studies, we synthesized surface modification materials bearing ferrocene as a redox active moiety to explore features of the modified surfaces by an electrochemical method using cyclic voltammetry, where surface concentrations of immobilized molecule and blocking effect to obtain insight for density leading to a close-packed layer were available.According to those findings, fabrication of biosensing interface on the silica sensing chip of the waveguide-mode sensor was carried out using triethoxysilane derivatives bearing succinimide ester and oligoethylene glycol moieties to immobilize antibody and to suppress nonspecific adsorption of proteins, respectively. The results demonstrate that the waveguide-mode sensor powered by the biosensing interface fabricated with those triethoxysilane derivatives and antibody has potential to detect several tens ng/mL of biomarkers in human serum with unlabeled detection method.

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Section: Surface Modification Of Gc and Hopg With Close-packed Monolayermentioning

confidence: 99%

Fabrication of Biosensing Interface with Monolayers

Tanaka

Niwa

2020

ANAL. SCI.

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“…Iodine plasma can roughen the surface hence, using plasma of optimized power for an optimized time is crucial. The surface constructs explored to demonstrate the scope of this new carbon electrode modification strategy are shown in Scheme 6.7 [123]. As the strength of the carbon-iodine bond is less, modification of the iodinated PPF surface with both alkenes and alkynes was conducted with visible light ( = 514 nm).…”

Section: Hydrogenation and Halogenation Of Carbonmentioning

confidence: 99%

Modification of Carbon Electrode Surfaces

Alam

Gooding

2015

Advances in Electrochemical Sciences and Engineering

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“…Hydrogenation of GCE: H-termination of the GCEs was performed electrochemically as described previously for boron-doped diamond substrates [21] with some minor modifications. Briefly, the GCE was immersed in 2 m HCl and used as the cathode, and a platinum wire, immersed in 2 m H 2 SO 4 solution, was used as the anode.…”

Section: Electrode Preparationmentioning

confidence: 99%

“…[20] Recently, the feasibility of attaching iodine atoms to carbon films formed by photoresist pyrolysis with iodine plasma and the subsequent linking of both alkenes and alkynes to the iodinated surface has been demonstrated. [21] As another alternative, electrochemical methods for either the chlorination or hydrogenation of surfaces are attractive because of their simplicity, the ability to control the modification process, and reduced surface damage. Electrochemical hydrogenation of boron-doped diamond [22a] and germanium [22b] has been reported, and there have been several reports on the electrochemical conversion of CÀH to CÀX (X= F or Cl) for the functionalization of organic molecules.…”

Section: Introductionmentioning

confidence: 99%

“…An alternative approach exploits the photochemical grafting of organic alkenes to link functional organic molecules to carbon surfaces including diamond,1 amorphous carbon,15a glassy carbon (GC),19 highly ordered pyrolitic graphite (HOPG),13a, 14 and carbon nanofibers 20. Recently, the feasibility of attaching iodine atoms to carbon films formed by photoresist pyrolysis with iodine plasma and the subsequent linking of both alkenes and alkynes to the iodinated surface has been demonstrated 21…”

Section: Introductionmentioning

confidence: 99%

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Facile Electrochemical Hydrogenation and Chlorination of Glassy Carbon to Produce Highly Reactive and Uniform Surfaces for Stable Anchoring of Thiolated Molecules

Debela

Ortiz

Beni

et al. 2014

Chemistry A European J

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Carbon is a highly adaptable family of materials and is one of the most chemically stable materials known, providing a remarkable platform for the development of tunable molecular interfaces. Herein, we report a two-step process for the electrochemical hydrogenation of glassy carbon followed by either chemical or electrochemical chlorination to provide a highly reactive surface for further functionalization. The carbon surface at each stage of the process is characterized by AFM, SEM, Raman, attenuated total reflectance (ATR) FTIR, X-ray photoelectron spectroscopy (XPS), and electroanalytical techniques. Electrochemical chlorination of hydrogen-terminated surfaces is achieved in just 5 min at room temperature with hydrochloric acid, and chemical chlorination is performed with phosphorus pentachloride at 50 °C over a three-hour period. A more controlled and uniform surface is obtained using the electrochemical approach, as chemical chlorination is observed to damage the glassy carbon surface. A ferrocene-labeled alkylthiol is used as a model system to demonstrate the genericity and potential application of the highly reactive chlorinated surface formed, and the methodology is optimized. This process is then applied to thiolated DNA, and the functionality of the immobilized DNA probe is demonstrated. XPS reveals the covalent bond formed to be a C-S bond. The thermal stability of the thiolated molecules anchored on the glassy carbon is evaluated, and is found to be far superior to that on gold surfaces. This is the first report on the electrochemical hydrogenation and electrochemical chlorination of a glassy carbon surface, and this facile process can be applied to the highly stable functionalization of carbon surfaces with a plethora of diverse molecules, finding widespread applications.

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Light-Induced Organic Monolayer Modification of Iodinated Carbon Electrodes

Cited by 9 publications

References 65 publications

Fabrication of Biosensing Interface with Monolayers

Fabrication of Biosensing Interface with Monolayers

Modification of Carbon Electrode Surfaces

Facile Electrochemical Hydrogenation and Chlorination of Glassy Carbon to Produce Highly Reactive and Uniform Surfaces for Stable Anchoring of Thiolated Molecules

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