Atomic Structure and Dynamics of Metal Dopant Pairs in Graphene

He, Zhengyu; He, Kui; Robertson, Alex W.; Kirkland, Angus I.; Kim, Dong-Wook; Ihm, Jisoon; Yoon, Euijoon; Lee, Gun-Do; Warner, Jamie H.

doi:10.1021/nl500682j

Cited by 245 publications

(174 citation statements)

References 36 publications

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“…Nevertheless, the major source of the magnetism in two systems is quite different. These fascinating phenomenon, in combination with the fact that the substitutional 2D materials has been artificially synthesis by many groups [47][48][49][50][51][52][53], can paves a new route at nanoscale for novel functionalities of optical and spintronics devices.…”

Section: Discussionmentioning

confidence: 99%

A first-principles study of light non-metallic atom substituted blue phosphorene

Sun

Tang

Ren

et al. 2015

Applied Surface Science

101

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Section: Discussionmentioning

confidence: 99%

A first-principles study of light non-metallic atom substituted blue phosphorene

Sun

Tang

Ren

et al. 2015

Applied Surface Science

101

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“…However, no such materials have been synthesised for CO 2 reduction as synthesis of single atom catalysts is often quite difficult and requires appropriate support structures for the particular application. [60][61][62] For Type I materials, trace levels of metal nanoparticles have shown to significantly enhance the CO 2 RR activity of graphene [23] and recent studies have also extended this to N-graphene. [63,64] Monodisperse Cu NPs supported by pyridinic-N graphene (p-NG) and were found to be selective for CO 2 reduction to ethylene.…”

Section: Graphene Supported Nanoparticlesmentioning

confidence: 99%

“…[108] Further, these materials maximise metal utilisation and can greatly improve catalytic efficiency. [109,110] Motivated by the work of He et al, [60] DFT studies were extended to investigate transition metal dopant pairs (dimers) on graphene supports in order to reveal whether these dispersed metal centres can be tuned to CO 2 RR. [107] The computational hydrogen electrode (CHE) was utilised to elucidate free energy profiles, electrocatalytic performance and reaction pathways and it was found that dimer geometry and configuration on the graphene support plays a very important role in the adsorption of intermediate species.…”

Section: Nanostructured Carbon Supportsmentioning

confidence: 99%

Carbon Solving Carbon's Problems: Recent Progress of Nanostructured Carbon‐Based Catalysts for the Electrochemical Reduction of CO₂

Vasileff

Zheng

Qiao

2017

Advanced Energy Materials

353

222

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The electrochemical reduction of CO2 to useful molecules offers an elegant technological solution to current energy security and sustainability issues because it sequesters carbon from the atmosphere, provides an energy storage solution for intermittent renewable sources, and can be used to produce fuels and industrial chemicals. Nanostructured carbon materials have been extensively used to catalyse some key electrochemical processes because of their excellent electrical conductivity, chemical stability, and abundant active sites. This progress report focuses on nanostructured carbon materials, namely graphene materials, carbon nanotubes, porphyrin materials, nanodiamond, and glassy carbon, which have recently shown promise as high performing CO2 reduction electrocatalysts and supports. Along with discussion regarding materials synthesis, structural characterisation, and electrochemical performance characterisation techniques used, this report will discuss the findings of recent computational CO2RR studies which have been key to elucidating active sites and reaction mechanisms, and developing strategies to break conventional scaling relationships. Lastly, challenges and future perspective of these carbon‐based materials for CO2 reduction applications will be given. Much work is still required to realise the commercial viability of the technology, but advanced experimental techniques coupled with theoretical calculations are expected to facilitate future development of the technology.

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“…The question of whether dispersed atomic sites can be tuned to reductive conversion of CO 2 using a different supporting material then arises. Here, inspired by the successful fabrication of graphene-supported Fe dopant pairs, 28 we systematically investigate CO 2 electroreduction on various graphene-supported first-row transition metal dopant pairs. The adjacent graphene single vacancy supported Cu 2 , MnCu, and NiCu pair dopants are identified as promising candidates for catalyzing CO 2 electroreduction to CO, CH 4 , and CH 3 OH, respectively, with a substantially reduced overpotential.…”

Section: Introductionmentioning

confidence: 99%

CO₂ Electroreduction Performance of Transition Metal Dimers Supported on Graphene: A Theoretical Study

et al. 2015

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Graphene-based materials are being hotly pursued for energy and environment applications. Inspired by the recent experimental synthesis of Fe 2 dimer supported on graphene (He, Z.; He, K.; Robertson, A. W.; Kirkland, A. I.; Kim, D.; Ihm, J.; Yoon, E.; Lee, G.-D.; Warner, J. H. Nano Lett. 2014, 14, 3766−3772), here using large-scale screening-based density functional theory and microkinetics modeling, we have identified that some transition metal dimers (Cu 2 , CuMn, and CuNi), when supported on graphene with adjacent single vacancies (labeled as XY@2SV), perform better in CO 2 electroreduction with reduced overpotental and enhanced current density. Specifically, Cu 2 @2SV is catalytically active toward CO production, similar to Au electrodes but distinct from bulk Cu; MnCu@2SV is selective toward CH 4 generation, while NiCu@2SV promotes CH 3 OH production because of the difference in oxophilicity between incorporated Mn and Ni. The advantages of the outstanding selectivity of products, the high dispersity of spatial distribution, and the reduced overpotentials allow these new systems to be promising catalysts, which will motivate more experimental research in this direction to further explore graphenebased materials for CO 2 conversion.

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Atomic Structure and Dynamics of Metal Dopant Pairs in Graphene

Cited by 245 publications

References 36 publications

A first-principles study of light non-metallic atom substituted blue phosphorene

A first-principles study of light non-metallic atom substituted blue phosphorene

Carbon Solving Carbon's Problems: Recent Progress of Nanostructured Carbon‐Based Catalysts for the Electrochemical Reduction of CO₂

CO₂ Electroreduction Performance of Transition Metal Dimers Supported on Graphene: A Theoretical Study

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Atomic Structure and Dynamics of Metal Dopant Pairs in Graphene

Cited by 245 publications

References 36 publications

A first-principles study of light non-metallic atom substituted blue phosphorene

A first-principles study of light non-metallic atom substituted blue phosphorene

Carbon Solving Carbon's Problems: Recent Progress of Nanostructured Carbon‐Based Catalysts for the Electrochemical Reduction of CO2

CO2 Electroreduction Performance of Transition Metal Dimers Supported on Graphene: A Theoretical Study

Contact Info

Product

Resources

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Carbon Solving Carbon's Problems: Recent Progress of Nanostructured Carbon‐Based Catalysts for the Electrochemical Reduction of CO₂

CO₂ Electroreduction Performance of Transition Metal Dimers Supported on Graphene: A Theoretical Study