Naphthalene on Ni(111): Experimental and Theoretical Insights into Adsorption, Dehydrogenation, and Carbon Passivation

Yazdi, Milad Ghadami; Moud, Pouya H.; Marks, Kess; Piskorz, Witold; Öström, Henrik; Hansson, Tony; Kotarba, Andrzej; Engvall, Klas; Göthelid, Mats

doi:10.1021/acs.jpcc.7b07757

Cited by 15 publications

(30 citation statements)

References 41 publications

(92 reference statements)

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“…In both cases, the only desorption process observed is the desorption of molecular hydrogen accompanied by irreversible structural changes in the naphthalene overlayer. This is consistent with the findings of Yazdi et al 7 where scanning tunneling microscopy (STM) and TPD were used to study naphthalene on Ni(111). H 2 desorption coincides with the disappearance of ordered naphthalene patches in the temperature range of 380-600 K with the first desorption peak at 450 K. At temperatures above 580 K, carbon chain and network growth is reported, and it is assumed that a graphenelike layer is formed.…”

Section: Introductionsupporting

confidence: 91%

“…Santarossa et al 14 used density functional theory (DFT) calculations to show that a flat lying di-bridge-7 is the optimal adsorption configuration of naphthalene on Pt, Pd, and Rh. Similar findings were recently reported by Kolsbjerg et al 24 for naphthalene on Pt(111) and by Yazdi et al 7 for naphthalene on Ni(111) where the di-bridge-7 is the most favored configuration. Additionally, DFT calculations by Yazdi et al show that the adsorption of naphthalene is accompanied by a pronounced de-aromatization, similar to that seen for benzene on Ni(100) and Cu(110).…”

Section: Introductionsupporting

confidence: 90%

“…In a previous structural investigation of naphthalene on Ni(111), 7 we have shown that naphthalene molecules adsorb flat on smooth terraces, preferring a geometry of aromatic rings positioned over Ni-bridge sites. Temperature programmed desorption (TPD) showed that desorption of H 2 occurs in two steps, where the second step coincides with the conversion of carbon atoms to a graphenelike structure, causing rapid passivation of the catalyst.…”

Section: Introductionmentioning

confidence: 80%

“…45 A 5 L dose at 110 K results in a chemisorbed monolayer and a physisorbed multilayer of naphthalene. 7 In the spectrum recorded after dosing at 110 K, one sharp resonance is observed at 3057 cm −1 , corresponding to multilayer naphthalene, in addition to the nonresonant background. The observed resonant frequency is in the middle of the aromatic C-H stretching region and matches the frequencies found by Jakob and Menzel 46 and Lehwald et al 47 for multilayer benzene on Ru(001) and Ni(111), respectively.…”

Section: Sfg Measurementsmentioning

confidence: 99%

“…Temperature programmed desorption (TPD) showed that desorption of H 2 occurs in two steps, where the second step coincides with the conversion of carbon atoms to a graphenelike structure, causing rapid passivation of the catalyst. 7 In the present study, we aim to elucidate the mechanism of naphthalene dehydrogenation and graphene formation on the Ni(111) surface by investigating the surface species during the temperature dependent dehydrogenation.…”

Section: Introductionmentioning

confidence: 99%

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Investigation of the surface species during temperature dependent dehydrogenation of naphthalene on Ni(111)

Marks

Yazdi

Piskorz

et al. 2019

The Journal of Chemical Physics

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The temperature dependent dehydrogenation of naphthalene on Ni(111) has been investigated using vibrational sum-frequency generation spectroscopy, X-ray photoelectron spectroscopy, scanning tunneling microscopy, and density functional theory with the aim of discerning the reaction mechanism and the intermediates on the surface. At 110 K, multiple layers of naphthalene adsorb on Ni(111); the first layer is a flat lying chemisorbed monolayer, whereas the next layer(s) consist of physisorbed naphthalene. The aromaticity of the carbon rings in the first layer is reduced due to bonding to the surface Ni-atoms. Heating at 200 K causes desorption of the multilayers. At 360 K, the chemisorbed naphthalene monolayer starts dehydrogenating and the geometry of the molecules changes as the dehydrogenated carbon atoms coordinate to the nickel surface; thus, the molecule tilts with respect to the surface, recovering some of its original aromaticity. This effect peaks at 400 K and coincides with hydrogen desorption. Increasing the temperature leads to further dehydrogenation and production of H 2 gas, as well as the formation of carbidic and graphitic surface carbon.

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Section: Introductionsupporting

confidence: 91%

Section: Introductionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 80%

Section: Sfg Measurementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Investigation of the surface species during temperature dependent dehydrogenation of naphthalene on Ni(111)

Marks

Yazdi

Piskorz

et al. 2019

The Journal of Chemical Physics

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Effect of Nickel Acetyl Acetonate as Lubricant Additive in Base Oils with Different Molecular Structure on In-Situ Formation and Tribomechanism of Carbon-Based Tribofilms of Steel-Steel Sliding Pair

Peng,

Fan,

Song

et al. 2024

Tribol Lett

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Nickel acetyl acetonate (Ni(acac) 2 ), a metal-organic compound, was directly dispersed in base oils alkylated naphthalene (AN-5), diisooctyl sebacate (DIOS), poly-α-ole n (PAO6), and 150N in the presence of commercial dispersant RF1151 (monoallyl poly(isobutylene succinimide). The tribological properties of the lubricants were tested with a four-ball friction and wear tester. The friction-induced in-situ formation of carbon lms on rubbed steel surfaces under the catalysis of Ni(acac) 2 was investigated, and the as-formed carbon lms were characterized by scanning electron microscopy, Raman spectroscopy, and X-ray photoelectron spectroscopy. The results show that Ni(acac) 2 added in the base oils can release metallic Ni to form nickel layer on the rubbed metal sub-surfaces and catalyze the degradation of the base oil molecules adsorbed to form carbon-based tribo lms. The carbon lm formed from AN-5 with six-membered ring structure has a high degree of graphitization and the best frictionreducing and antiwear abilities, and those formed from PAO6 and 150N with linear structure have a low degree of graphitization as well as good tribological properties. Under the lubrication of DIOS with Ni(acac) 2 , however, there is no carbon lm formation while the tribological properties of the lubricant are relatively poor, due to the absence of the catalytic metallic Ni and nickel oxide layer on the rubbed metal sub-surface. Thanks to the catalytic effect of metallic Ni released from Ni(acac) 2 for the degradation of various base oils with different molecular structure, the present approach could provide a rational pathway to tune the in-situ formation of carbon-based tribo lm on rubbed steel surfaces so as to effectively reduce the friction and wear of steel-steel sliding pair.

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Unravelling the significance of catalyst reduction stage for high tar reforming activity in the presence of syngas impurities

Mohamed¹,

Veksha²,

Ha³

et al. 2022

Applied Catalysis A: General

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Naphthalene on Ni(111): Experimental and Theoretical Insights into Adsorption, Dehydrogenation, and Carbon Passivation

Cited by 15 publications

References 41 publications

Investigation of the surface species during temperature dependent dehydrogenation of naphthalene on Ni(111)

Investigation of the surface species during temperature dependent dehydrogenation of naphthalene on Ni(111)

Effect of Nickel Acetyl Acetonate as Lubricant Additive in Base Oils with Different Molecular Structure on In-Situ Formation and Tribomechanism of Carbon-Based Tribofilms of Steel-Steel Sliding Pair

Unravelling the significance of catalyst reduction stage for high tar reforming activity in the presence of syngas impurities

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