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https://hdl.handle.net/11499/47445
Title: | Mechanism of methanol decomposition on the Cu-Embedded graphene: A DFT study | Authors: | Akça, Aykan Karaman, Onur Karimi-Maleh, Hassan Karimi, Fatemeh Karaman, Ceren Atar, Necip Yola, Mehmet Lütfi Erk, Nevin |
Keywords: | Cu-embedded graphene Density functional theory Methanol decomposition Reaction mechanism Carrier concentration Catalyst activity Catalyst poisoning Chemical bonds Degradation Direct methanol fuel cells (DMFC) Electron density measurement Graphene Methanol Methanol fuels Reaction intermediates Cu-embedded graphene Decomposition reaction Density difference Density-functional-theory DFT study Intermediate state Methanol decomposition O-H bond Reaction mechanism Via density Density functional theory |
Publisher: | Elsevier Ltd | Abstract: | The methanol decomposition reaction has gained substantial attention due to the wide range of applications that its intermediates offer. In this work, methanol (CH3OH) decomposition on Copper-embedded graphene (CuG) surface has been investigated via density functional theory with Grimme-D2 dispersion correction. The charge density of the CuG surface has been analyzed and the redistribution of the electron density of the surface has been represented via the electron density difference (EDD) map. Moreover, the decomposition reaction mechanism of CH3OH on the CuG surface through the cleavage of C–H, O–H and C–O bonds has been investigated in detail. In the initial state, the C–O and O–H bonds of CH3OH have similar activation barriers, thereby the adsorption and degradation mechanism of the intermediate states arising through O–H bond cleavage on the CuG surface has been investigated. In addition, the charge density calculations of the transition state geometries have been conducted and examined with EDD maps. The results have revealed that the previously adsorbed oxygen molecule exhibited high catalytic activity towards O–H decomposition compared to the bare surface. The CuG surface has offered higher activity on the C–H bonds compared to the C–O bonds of the intermediate states generated by CH3OH decomposition. The results revealed that the proposed CuG structure can be utilized as an alternative electrode catalyst that can prevent the CO poisoning issue in direct methanol fuel cells. © 2021 Hydrogen Energy Publications LLC | URI: | https://doi.org/10.1016/j.ijhydene.2021.09.028 https://hdl.handle.net/11499/47445 |
ISSN: | 0360-3199 |
Appears in Collections: | Mühendislik Fakültesi Koleksiyonu Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection |
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