Holey Graphene: Topological Control of Electronic Properties and Electric Conductivity

Barkov, Pavel V.; Glukhova, Olga E.

doi:10.3390/nano11051074

Cited by 12 publications

(10 citation statements)

References 34 publications

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“…Thus, the presence of GNM with the triangle hole is highly improbable, it will be completed to holes of other geometric forms or will be filled by atoms of other types. By the original methodic, the virtual growing of CNT (11,10) from the obtained GNM supercells was performed. It was found that the growing of VACNT(11,10)-graphene from GNM with the circle form is the most energetically favorable since it has the lowest energy barrier 0.014 eV/atom.…”

Section: Discussionmentioning

confidence: 99%

“…We chose CNT (11,10) for growing since it had the smallest radius from the most often synthesized CNTs [29][30][31]. Merging CNT and GNM was performed by the original methodic that provides building seamless junctions of carbon nanostructures [32].…”

Section: Virtual Growing Of Vacnt(1110)-graphenementioning

confidence: 99%

“…As it seen from Figure 4, the lowest energy matches to the structure with the hexagonal hole (−47.23 eV/atom). GNM with holes with the circle hole, so the growing of VACNT (11,10)-graphene from GNM with the circle hole is the least energy-consuming. For comparison, the energy barrier in the case of the circle and square forms equals 0.021 eV/atom, in the case of the triangle hole-0.016 eV/atom.…”

Section: Virtual Growing Of Vacnt(1110)-graphenementioning

confidence: 99%

“…[7]. GNM demonstrates a band gap (BG) that can be tuned by changing the neck's width (the distance between neighbor holes) and nanohole's topology [8][9][10][11]. It was shown that a field-effect transistor on the base of GNM surpasses its graphene analogue in terms of output conductance, voltage gain, and maximum oscillation frequency [12].…”

Section: Introductionmentioning

confidence: 99%

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The Influence of Hydrogen Passivation on Conductive Properties of Graphene Nanomesh—Prospect Material for Carbon Nanotubes Growing

Shunaev

Glukhova

2022

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Graphene nanomesh (GNM) is one of the most intensively studied materials today. Chemical activity of atoms near GNM’s nanoholes provides favorable adsorption of different atoms and molecules, besides that, GNM is a prospect material for growing carbon nanotubes (CNTs) on its surface. This study calculates the dependence of CNT’s growing parameters on the geometrical form of a nanohole. It was determined by the original methodic that the CNT’s growing from circle nanoholes was the most energetically favorable. Another attractive property of GNM is a tunable gap in its band structure that depends on GNM’s topology. It is found by quantum chemical methods that the passivation of dangling bonds near the hole of hydrogen atoms decreases the conductance of the structure by 2–3.5 times. Controlling the GNM’s conductance may be an important tool for its application in nanoelectronics.

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Section: Discussionmentioning

confidence: 99%

Section: Virtual Growing Of Vacnt(1110)-graphenementioning

confidence: 99%

Section: Virtual Growing Of Vacnt(1110)-graphenementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Influence of Hydrogen Passivation on Conductive Properties of Graphene Nanomesh—Prospect Material for Carbon Nanotubes Growing

Shunaev

Glukhova

2022

Self Cite

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“…[2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] These 2D materials have received widespread attention because they exhibit outstanding features and properties in atomically thin 2D as compared with their bulk counterparts. [21][22][23][24][25][26][27][28][29] Their properties can be modified by chemical doping, creating vacancy/defect, or by the formation of heterostructures with the other 2D materials. [5,30,31] There is still a lot of scope for the search of other novel 2D materials with enchanting properties for their applications like electronics, DOI: 10.1002/adts.202200057 optoelectronics, spintronics, thermoelectric, gas sensing, storage, catalysis, etc.…”

Section: Introductionmentioning

confidence: 99%

Density Functional Theory‐Based Calculations for 2D Hexagonal Lanthanide Metals

Sangolkar

Jha

Pawar

2022

Advcd Theory and Sims

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Scrutiny of the stability, properties, and applications of 2D metals belonging to s-, p-, and d-block series has acquired intense research interest in the past few years. The present report is solely focused to systematically explore the stability and properties of 2D hexagonal (HX) lanthanides employing density functional theory calculations. To probe the dynamical stability of these materials, the phonon dispersion calculation is performed. The mechanical stability is analyzed on the basis of the 2D bulk modulus and elastic constant values. Further, to unravel the electronic properties of the 2D metals, electronic band structure, electron localization function, and the work function values are estimated. Moreover, en route to explore their magnetic properties, spin polarized density of states calculation is carried out and the ground state magnetic behavior is studied by considering ferromagnetic and antiferromagnetic spin configurations. Result explicitly demonstrates that 11 lanthanide metals are dynamically stable as an atomically thin 2D HX films. All of them are conducting in nature exhibiting ferromagnetic behavior in their ground state. These results offer the fundamentals of stability and properties of 2D HX lanthanides which can lay the foundation for exploring their diverse future applications.

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Structure, Stability, Properties, and Application of Atomically Thin Coinage Metal Flatland in Graphene Pore: A Density Functional Theory Calculation

Sangolkar

Pawar

2021

Physica Status Solidi (b)

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2D metals are emerging materials in the 2D nanomaterials family and a rapid development is seen in the past few years. The properties of material that play a crucial role to determine their application in various fields need to be explored. Herein, a patch consisting of seven to nine coinage metal (Cu, Ag, and Au) atoms is created in the pore of graphene. Electronic properties, work function, and the interaction energy using periodic energy decomposition analysis (pEDA) of the materials are calculated using density functional theory (DFT). Carbon monoxide (CO) adsorption studies on these surfaces are also performed. All the metal atoms are found to align themselves in hexagonal arrangement in the graphene pore. All the materials with an exception of eight‐Au‐patched graphene are found to be metallic. The eight‐Au‐patched graphene is a low bandgap semiconductor exhibiting a direct bandgap of 0.23 eV. CO molecule adsorbs strongly on Cu‐patched surfaces in comparison to Ag‐ and Au‐patched surfaces. The interaction energy of CO is observed to be higher on seven‐Cu‐patched graphene as compared with Ag‐ and Au‐patched graphene.

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Holey Graphene: Topological Control of Electronic Properties and Electric Conductivity

Cited by 12 publications

References 34 publications

The Influence of Hydrogen Passivation on Conductive Properties of Graphene Nanomesh—Prospect Material for Carbon Nanotubes Growing

The Influence of Hydrogen Passivation on Conductive Properties of Graphene Nanomesh—Prospect Material for Carbon Nanotubes Growing

Density Functional Theory‐Based Calculations for 2D Hexagonal Lanthanide Metals

Structure, Stability, Properties, and Application of Atomically Thin Coinage Metal Flatland in Graphene Pore: A Density Functional Theory Calculation

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