通过第一原理模拟探索二维富勒烯网络中掺杂 BN 的影响

IF 5.9 3区材料科学 Q2 CHEMISTRY, PHYSICAL

FlatChem Pub Date : 2024-04-06 DOI:10.1016/j.flatc.2024.100655

Vivek K. Yadav

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The research findings indicate that the <math><mrow><mn>2</mn><mi>D</mi></mrow></math> sheets of <math><mrow><msub><mi>C</mi><mn>60</mn></msub><mo>,</mo><msub><mi>C</mi><mn>58</mn></msub><msub><mi>B</mi><mn>1</mn></msub><msub><mi>N</mi><mn>1</mn></msub></mrow></math>, and <math><mrow><msub><mi>C</mi><mn>54</mn></msub><msub><mi>B</mi><mn>3</mn></msub><msub><mi>N</mi><mn>3</mn></msub></mrow></math> exhibit band gaps of approximately <math><mrow><mn>0.97</mn><mi>e</mi><mi>V</mi><mo>(</mo><mn>1.51</mn><mi>e</mi><mi>V</mi><mo>)</mo><mo>,</mo><mn>1.08</mn><mi>e</mi><mi>V</mi><mo>(</mo><mn>1.65</mn><mi>e</mi><mi>V</mi><mo>)</mo></mrow></math>, and <math><mrow><mn>1.05</mn><mi>e</mi><mi>V</mi><mo>(</mo><mn>1.56</mn><mi>e</mi><mi>V</mi><mo>)</mo></mrow></math>, respectively, as obtained from PBE (HSE) calculations. 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引用次数: 0

摘要

在富勒烯 C60 中掺入硼和氮等较轻的非金属，是纳米电子器件领域的一大进步。与纯材料相比，这些掺杂的二维（2D）材料具有更高的稳定性和更强的吸附特性。值得注意的是，它具有半导体特性，因此具有更高的导电性和载流子迁移率。本研究探讨了富勒烯二维聚合物薄片的结构、电子、光学和电导率/载流子传输特性，包括掺杂和不掺杂硼和氮的情况。我们采用了具有 PBE 和 HSE 函数的密度泛函理论（DFT），并考虑了范德华（vdW）相互作用。研究结果表明，通过 PBE（HSE）计算得到的 C60、C58B1N1 和 C54B3N3 的二维薄片带隙分别约为 0.97eV（1.51eV）、1.08eV（1.65eV）和 1.05eV（1.56eV）。此外，根据形变势理论，C58B1N1 表现出超高导电率（室温下为 1014Ω-1cm-1s-1）。这些薄片的内聚能分别为 -8.76、-8.72 和 -8.67eV，表明其具有稳定性。这些结果很有希望，并强调了富勒烯单层中的单对 BN 掺杂剂对推动下一代二维纳米电子应用的重要意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Exploring the effect of BN doping in two-dimensional fullerene networks through first principle simulations

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Exploring the effect of BN doping in two-dimensional fullerene networks through first principle simulations

The doping of lighter non-metals like boron and nitrogen into fullerene $(C_{60})$ represents a promising advancement in the field of nanoelectronic devices. These doped two-dimensional (2D) materials offer improved stability and enhanced adsorption characteristics compared to pure form. Notably, It displays semiconducting behaviour, resulting in higher conductivity and carrier mobility. This study investigates the structural, electronic, optical, and conductivity/carrier transport properties of 2D polymer sheets made of fullerene, both with and without boron and nitrogen doping. We employ density functional theory (DFT) with PBE and HSE functionals, considering the inclusion of van der Waals (vdW) interactions. The research findings indicate that the $2 D$ sheets of $C_{60}, C_{58} B_{1} N_{1}$ , and $C_{54} B_{3} N_{3}$ exhibit band gaps of approximately $0.97 e V (1.51 e V), 1.08 e V (1.65 e V)$ , and $1.05 e V (1.56 e V)$ , respectively, as obtained from PBE (HSE) calculations. Moreover, according to the deformation potential theory, $C_{58} B_{1} N_{1}$ exhibit ultra-high conductivity ( $10^{14} Ω^{- 1} {c m}^{- 1} s^{- 1}$ at room temperature). These sheets display cohesive energies of −8.76, −8.72, and $- 8.67 e V$ , respectively, indicating their stability. These results are promising and underscore the significance of a single pair of $B N$ dopants in fullerene monolayers for advancing next-generation 2D nano-electronic applications.

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来源期刊

FlatChem Multiple-

CiteScore

8.40

自引率

6.50%

发文量

104

审稿时长

26 days

期刊介绍： FlatChem - Chemistry of Flat Materials, a new voice in the community, publishes original and significant, cutting-edge research related to the chemistry of graphene and related 2D & layered materials. The overall aim of the journal is to combine the chemistry and applications of these materials, where the submission of communications, full papers, and concepts should contain chemistry in a materials context, which can be both experimental and/or theoretical. In addition to original research articles, FlatChem also offers reviews, minireviews, highlights and perspectives on the future of this research area with the scientific leaders in fields related to Flat Materials. Topics of interest include, but are not limited to, the following: -Design, synthesis, applications and investigation of graphene, graphene related materials and other 2D & layered materials (for example Silicene, Germanene, Phosphorene, MXenes, Boron nitride, Transition metal dichalcogenides) -Characterization of these materials using all forms of spectroscopy and microscopy techniques -Chemical modification or functionalization and dispersion of these materials, as well as interactions with other materials -Exploring the surface chemistry of these materials for applications in: Sensors or detectors in electrochemical/Lab on a Chip devices, Composite materials, Membranes, Environment technology, Catalysis for energy storage and conversion (for example fuel cells, supercapacitors, batteries, hydrogen storage), Biomedical technology (drug delivery, biosensing, bioimaging)