Decomposition of methylamine on nitrogen atom modified Mo(100): a density functional theory study

Lv, Cun‐Qin; Liu, Jianhong; Guo, Yong; Wang, Gui‐Chang

doi:10.1039/c2cp24032g

Cited by 10 publications

(8 citation statements)

References 44 publications

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“…As displayed in Fig.5, the possible reaction pathways of methanol decomposition on Ru(0001) surface can be described as 9CH 3 OH→3CH 3 O+6CH 2 OH+9H→6CH 2 O+ 3CHOH+18H→7CHO+COH+CH+OH+26H→8CO+C+O+ 36H. Interestingly, during methanol decomposition, CHOH is the species most likely to break a C-O bond, similar to the phenomena observed during ethanol decomposition on Pt surfaces [28] and methylamine decomposition on 2N-Mo(100) [29] and Ru(0001) [30] surfaces, i.e., CH 3 CO and CH 2 CO are the species most likely to break the C-C bonds in ethanol, and CNH 2 , CHNH 2 and CHNH are the most likely intermediates formed on 2N-Mo(100) and Ru(0001) surfaces that activate the C-N bond in methylamine. …”

Section: Potential Energy Surfaces(pess) and Reaction Mechanisms On Tsupporting

confidence: 62%

Density functional theoretical studies on the methanol adsorption and decomposition on Ru(0001) surfaces

Liu

Lü

Jin

et al. 2016

Chem. Res. Chin. Univ.

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Periodic density functional theory(DFT) calculations are presented to describe the adsorption and decomposition of CH 3 OH on Ru(0001) surfaces with different coverages, including p(3×2), p(2×2), and p(2×1) unit cells, corresponding to monolayer(ML) coverages of 1/6, 1/4, and 1/2, respectively. The geometries and energies of all species involved in methanol dissociation were analyzed, and the initial decomposition reactions of methanol and the subsequent dehydrogenations reactions of CH 3 O and CH 2 OH were all computed at 1/2, 1/4, and 1/6 ML coverage on the Ru(0001) surface. The results show that coverage exerts some effects on the stable adsorption of CH 3 O, CH 2 OH, and CH 3 , that is, the lower the coverage, the stronger the adsorption. Coverage also exerts effects on the initial decomposition of methanol. C-H bond breakage is favored at 1/2 ML, whereas C-H and O-H bond cleavages are preferred at 1/4 and 1/6 ML on the Ru(0001) surface, respectively. At 1/4 ML coverage on the Ru(0001) surface, the overall reaction mechanism can be written as 9CH 3 OH→3CH 3 O+6CH 2 OH+9H→6CH 2 O+3CHOH+18H→ 7CHO+COH+CH+OH+26H→8CO+C+O+36H.

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Section: Potential Energy Surfaces(pess) and Reaction Mechanisms On Tsupporting

confidence: 62%

Density functional theoretical studies on the methanol adsorption and decomposition on Ru(0001) surfaces

Liu

Lü

Jin

et al. 2016

Chem. Res. Chin. Univ.

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“…5, the most favorable pathway for methylamine decomposition on Pt(100) can be described as H 3 CNH 2 / H 2 CNH 2 + H / H 2 CNH + 2H / HCNH + 3H / HCN + 4H / CN + 5H / CN + 5/2H 2 (g), and the production of CN by decomposition is consistent with the experimental ndings. 18 It is noteworthy that in methylamine decomposition on Pt(100) the C-N bond is not dissociated, which is the same as on Pd(111) 29 and different from on 2N-Mo(100) 28 and Ru(0001). 30 Moreover, the mechanism for methylamine decomposition is the same on Pt(100) and Pd(111), and the intermediates produced in methylamine decomposition are H 2 CNH 2 , H 2 CNH, HCNH, HCN, HNC and CN.…”

Section: Decomposition Potential Energy Surface (Pes)mentioning

confidence: 98%

“…Although massive amounts of information involving the decomposition of methylamine have been provided through experimental investigation, the detailed catalytic decomposition mechanisms of methylamine are still not clear. Recently, theoretical investigations have been applied to reveal the adsorption congurations of possible species involved in methylamine decomposition and the relevant reactions on transition metal surfaces, such as Si, 23,24 Ni, 25,26 Mo, 27,28 Pd, 29 Ru, 30 Co, 31 and Pt 32 surfaces, and on a B 12 N 12 nanocage. 33 On Si(100), Kato et al 24 found that N-H bond scission is preferential to C-N bond scission for methylamine decomposition under milder conditions, because of the charge transfer from the surface to the N atom, which weakens the N-H bond.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the reaction mechanism of methylamine decomposition on the N atom-modied Mo(100) surface has been determined, that is, the methyl group is dehydrogenated step by step to CNH 2 , C, NH 3 and H 2 . 28 On Pd(111) 29 and Ru(0001), 30 111), the amino and methyl groups are dehydrogenated step by step to HCN. 32 On the B 12 N 12 nanocage, Esrali et al 33 investigated methylamine decomposition via the breaking of the N-H and C-N bonds, and found that N-H bond breaking is the most favorable pathway.…”

Section: Introductionmentioning

confidence: 99%

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Adsorption and decomposition of methylamine on a Pt(100) surface: a density functional theory study

Liu

Jin

et al. 2015

RSC Adv.

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“…[21][22][23] Lv et al 24 carried out DFT modelling to understand the initial CH 3 NH 2 decomposition on Ni(111) and Ni(100), and found that CH 3 NH 2 scission sequence took place with the order of C-H > N-H > C-N. Moreover, they investigated CH 3 NH 2 decomposition on Mo(100) 25,26 and Pd(111), 27 and the results showed that the most likely decomposition pathway was CH 28 and Co(111), 29 and found that the reaction mechanism of the hydrogenation pathway on both surfaces was HCN / CNH 2 + HCNH / CH 2 NH / CH 2 NH 2 + CH 2 NH / CH 3 NH 2 . Platinum is an effective catalyst for the Andrussow and Degussa processes, 5,30,31 and the Pt(111) surface is oen considered because this most stable surface dominates in small particles used in catalysts.…”

Section: Introductionmentioning

confidence: 99%

Decomposition mechanism of methylamine to hydrogen cyanide on Pt(111): selectivity of the C–H, N–H and C–N bond scissions

Deng

Zhang

et al. 2014

RSC Adv.

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Periodic density functional theory (DFT) calculations were performed to systematically investigate the decomposition mechanism of methylamine (CH 3 NH 2 ) to hydrogen cyanide (HCN) on Pt(111). The geometries and energies for all species involved are analyzed, and the decomposition network is mapped out to elaborate the reaction mechanism. Our results show that the CH 3 NH 2 , methanimine (CH 2 NH) and HCN prefer to desorb, while the other species prefer to decompose; the decomposition pathway prefers the successive N-H bond scissions followed by the C-H bond scissions, that is, CH 3 NH 2 / CH 3 NH / CH 3 N / CH 2 N / HCN. The electronic structure and energy barrier analysis are used to identify the initial competitive scissions of C-H, N-H and C-N bonds. The interaction between fragments and surface in the TS plays a decisive role in controlling the energy barrier of initial CH 3 NH 2 decomposition on Pt(111). Finally, the Brønsted-Evans-Polanyi (BEP) relation identifies that the C-H and N-H bond scissions stay competitive, but the C-N bond scission is not facile to occur.

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Decomposition of methylamine on nitrogen atom modified Mo(100): a density functional theory study

Cited by 10 publications

References 44 publications

Density functional theoretical studies on the methanol adsorption and decomposition on Ru(0001) surfaces

Density functional theoretical studies on the methanol adsorption and decomposition on Ru(0001) surfaces

Adsorption and decomposition of methylamine on a Pt(100) surface: a density functional theory study

Decomposition mechanism of methylamine to hydrogen cyanide on Pt(111): selectivity of the C–H, N–H and C–N bond scissions

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