Investigation of glucose electrooxidation mechanism over N‐modified metal‐doped graphene electrode by density functional theory approach

Düzenli, Derya; Önal, Işık; Tezsevin, Ilker

doi:10.1002/jcc.26981

Cited by 4 publications

(1 citation statement)

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“…Therefore, searching for e cient electrocatalysts for C 6 H 12 O 6 oxidation is urgent and, also, an important challenge. Encouragingly, recent investigations have found that unsupported and supported Au-based catalysts are excellent candidates with no obvious poisoning [17][18][19][20][21]. Indeed, Cheng illustrated that the Au(111) surface capped with chiral phenylalanine shows good C 6 H 12 O 6 oxidation reactivity by DFT calculations [17].…”

Section: Introductionmentioning

confidence: 99%

Theoretical study on the adsorption and oxidation of glucose on Au(111) surface

et al. 2023

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Context While Au-based catalysts recently have shown tremendous potential in glucose oxidation to gluconic acid, the detailed reaction mechanism is still unclear, which impedes the development of direct glucose fuel cell (DGFC). Methods Using density functional theory (DFT), we exhibit some new adsorption con gurations and oxidation mechanisms by considering both the open chain form and the ring form of glucose on Au(111) surface in the presence of OH. The strong interactions between glucose and the OH adsorbed surface are obtained. Moreover, form the calculated energy pathways, the oxidation of glucose in the open chain involves the dissociation of the formyl C−H bond by the adsorbed OH, while the ring form glucose oxidation is initiated by O−H bond rupture rather than C−H bond scission and preferentially undergoes the ring-open process to generate the open chain form glucose. Meanwhile, the results demonstrate that the adsorbed OH assists in reducing the activation energy of reaction process.

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Section: Introductionmentioning

confidence: 99%

Theoretical study on the adsorption and oxidation of glucose on Au(111) surface

et al. 2023

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Investigation of glucose electrooxidation mechanism over N‐modified metal‐doped graphene electrode by density functional theory approach

2022

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In this work, various precious and non‐precious metals reported in the literature as the most effective catalysts for glucose electrooxidation reaction were investigated by the density functional theory (DFT) approach in order to reveal the mechanisms taking place over the catalysts in the fuel cell. The use of a single‐atom catalyst model was adopted by insertion of one Au, Cu, Ni, Pd, Pt, and Zn metal atom on the pyridinic N atoms doped graphene surface (NG). β form of d‐glucose in alkaline solution was used to determine the reaction mechanism and intermediates that formed during the reaction. DFT results showed that the desired glucono‐lactone was formed on the Cu‐3NG electrode in a single‐step reaction pathway whereas it was produced via different two‐step pathways on the Au and Pt‐3NG electrodes. Although the interaction of glucose with Ni, Pd, and Zn‐doped surfaces resulted in the deprotonation of the molecule, lactone product formation did not occur on these electrode surfaces. When the calculation results are evaluated in terms of energy content and product formation, it can be concluded that Cu, Pt, and especially Au doped graphene catalysts are effective for direct glucose oxidation in fuel cells reactor.

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