Nitrogen‐Doped sp<sup>2</sup>‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Gao, Yongjun; Hu, Gang; Zhong, Jun; Shi, Zujin; Zhu, Yuanshuai; Su, Dang Sheng; Wang, Jianguo; Bao, Xinhe; Ma, Ding

doi:10.1002/anie.201207918

Cited by 475 publications

(399 citation statements)

References 33 publications

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“…The catalytic performance was evaluated using the model reaction between aniline and formic acid under an additive-free and solvothermal one-pot condition (140°C, 10 h), in comparison to mono-and tri-metallic catalysts (Table 1 and see ESI † Supplementary Table S4). Both monometallic Pd/N-rGO and commercial Pd/C catalysts produced a mixture of cyclohexanone and dicyclohexylamine via active hydrogenation, as expected (entries 1 and 2, Table 1), which was consistent with the reported results, [21][22][23][24][25] while a metal-free carbocatalyst (GO and N-rGO) 28,29 and mono-metals (Ag, Co, Au, Pt, Ni and Sn) loaded on N-rGO showed almost no catalytic effect (see ESI † entries 1-10, Supplementary Table S4). Positively, the Pd-based bimetallic nano-alloys with transition metals (Co, Au, Pt, Sn and Ni) produced N-methyl-N-phenylformamide (5) as a methylation product in a yield range of 18-70% (entries 3-7, Table 1).…”

Section: Resultssupporting

confidence: 89%

“…Three N1s peaks at~399, 400 and 402 eV were assigned to the pyridinic, pyrolic and graphitic or quaternary N (see ESI † Supplementary Figure S4c). 28,29,31 The large amount of nitrogen (~4 at %) and oxygen atoms (~18 at %) in Supplementary Table S5 coordinated metal NPs on the graphene in a well dispersed and stable manner, preventing the re-oxidation of noble metal M 0 (M = Ag, Pd), as reported for N-doped carbon. 15,32 Therefore, a structural model of Pd 47 Ag 53 /Fe 3 O 4 /N-rGO could be hypothetically proposed (in ESI † Supplementary Scheme S1).…”

Section: Resultsmentioning

confidence: 80%

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Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

2015

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The methylation of amines for the synthesis of methylamines and dimethylamines as platform chemicals has been attempted mostly by homogeneous catalysts with acid additives. However, there are scarcely any reports on heterogeneous catalytic methylation reactions except for a routine approach under high temperature and high pressure of CO 2 and H 2 gases for extended reaction times. Here we report a heterogeneously catalyzed selective methylation of aromatic amines using reactive and nontoxic formic acid as the only source for the construction of methyl groups, under ambient pressure in an additive-free one-pot reaction condition. Equal proportions of Pd and Ag in the PdAg/Fe 3 O 4 /N-rGO catalyst deliver highly selective amine methylation without aromatic ring hydrogenation, as the strained Pd in the alloy is combined with the graphene-derived support, preventing nanoparticle agglomeration and the action of magnetite as a promoter. Both N-methylation and N,N-dimethylation of various substituted aromatic amines were performed with complete conversion and excellent 90-97% selectivity by controlling the reaction times in the range of 10-24 h at 140°C without unwanted aromatic ring hydrogenation. Furthermore, the developed bimetallic catalyst provided high yields (88-91%) of methylation with CO 2 +H 2 gas under high pressure, which are as good as the results of homogenous catalysts with an acid additive. To the best of our knowledge, our use of this environmentally friendly methodology is the first time that this durable heterogeneous catalyst has readily performed highly selective methylation at ambient pressure, which is attractive for industrial applications.

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Section: Resultssupporting

confidence: 89%

Section: Resultsmentioning

confidence: 80%

Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

2015

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“…This could be helpful for highly active photocatalytic processes. [ 43,56 ] It also renews the understanding of role of oxygen-containing functional groups in GO and its part-reduced derivatives. Moreover, a greater understanding of the fundamental physics of carbon nanomaterials will eventually be a benefi t for design and fabrication of novel carbon-based nano optical-electronic devices in the not-too-distant future.…”

mentioning

confidence: 97%

Direct Observation of Quantum‐Confined Graphene‐Like States and Novel Hybrid States in Graphene Oxide by Transient Spectroscopy

Wang

et al. 2013

Advanced Materials

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Quantum-confined graphene-like electronic states are directly observed in graphene oxide and photothermally reduced graphene oxide via transient spectroscopy. An unexpected novel hybrid state arising from amorphous carbon-like peripheral structure with high sp(3) /sp(2) carbon ratio in close vicinity of confined graphene-like states is found commonly existent in various carbon nanomaterials, including graphene oxide, graphene quantum dots, and carbon dots.

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“…Graphene is considered as an interesting, exciting, and eye-capturing two-dimensional (2-D) structure formed by the sp 2 hybridized carbon [145][146][147][148][149]. The nitrogenenriched graphene (NG) materials have been prepared by the various synthesis techniques and routes ( Figure 7) [151,152] in order to meet the desired requirements for the various electrochemical and biochemical applications [139,[153][154][155][156].…”

Section: Graphenementioning

confidence: 99%

Synthesis and electrochemical applications of nitrogen-doped carbon nanomaterials

Majeed¹,

Zhao²,

Zhang³

et al. 2013

Nanotechnology Reviews

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Abstract:Nitrogen doping is an effective way to tailor the properties of the shaped carbon materials, including the nanotubes, nanocups, nanofibers, as well as the nanorods, and render their potential use for various applications. The common bonding configurations obtained on the N insertion is the pyridinic N and pyrrolic N, which impart the characteristic properties to these carbon materials. This review will focus on the nitrogen-doped carbon materials, the doping effect on the electrochemistry of the doped nanomaterials, and the various synthetic methods to introduce N into the carbon network. The potential applications of the N-doped materials are also reviewed on the basis of the experimental and theoretical studies in electrochemistry.

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Nitrogen‐Doped sp²‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Cited by 475 publications

References 33 publications

Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

Direct Observation of Quantum‐Confined Graphene‐Like States and Novel Hybrid States in Graphene Oxide by Transient Spectroscopy

Synthesis and electrochemical applications of nitrogen-doped carbon nanomaterials

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Nitrogen‐Doped sp2‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation

Cited by 475 publications

References 33 publications

Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

Heterogeneous PdAg alloy catalyst for selective methylation of aromatic amines with formic acid under an additive-free and solvothermal one-pot condition

Direct Observation of Quantum‐Confined Graphene‐Like States and Novel Hybrid States in Graphene Oxide by Transient Spectroscopy

Synthesis and electrochemical applications of nitrogen-doped carbon nanomaterials

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Nitrogen‐Doped sp²‐Hybridized Carbon as a Superior Catalyst for Selective Oxidation