A superhard sp$^{2}$-sp$^{3}$ hybridized orthorhombic carbon allotrope with conductive property under extreme pressure

Electronic Structure Pub Date : 2024-01-18 DOI:10.1088/2516-1075/ad2004

DR Neetik Mukherjee, Gaurav Shukla, Ashwani Kumar Tiwari

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引用次数: 0

Abstract

Superhard materials with conductive properties are extremely important. They have potential applications in multifunctional devices under extreme natural conditions. Here we present a superhard and conductive sp$^{2}$-sp$^{3}$ mixed hybrid carbon allotrope through Density functional theory calculations. The proposed carbon phase contains 36 atoms in an orthorhombic unit cell with \emph{Pmmm} symmetry. In present structure (namely poC$_{36}$), the sp$^{2}$ bonds are wrapped around inside the sp$^{3}$ bonded network. At 0 GPa it is dynamically stable and energetically more favourable than fullerene C$_{60}$, graphene, Orth-C$_{10}$, orth-C$^{`}_{10}$, oC$_{36}$, C$_{48}$, C20-sc, C21-sc, M-carbon, W-carbon etc. At 47.2 GPa pressure it's energy becomes lower than graphite. The Vickers hardness value is 76.32 GPa, which is higher than cubic boron nitride, the second hardest material. At 0 GPa it is an indirect band gap semi-conductor with band gap 0.08 eV. At around 11 GPa pressure, the valence band crosses the conduction band generating 1-D conductivity in poC$_{36}$. These, interesting features make poC$_{36}$ a useful material for mechanical tools and electronic devices. The Raman spectra exhibits a diamond-like band, alongside graphite-like G and D bands, all of which undergo rightward shifts with increasing pressure, indicating structural changes. X-ray diffraction at 0 GPa resembles diamond, but at 47 GPa, four peaks vanish while six new ones emerge, signifying significant structural alterations under high pressure.

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一种在极压下具有导电特性的超硬 sp$^{2}$-sp$^{3}$ 杂化正交碳同素异形体

具有导电性能的超硬材料极为重要。它们有望应用于极端自然条件下的多功能设备。在此，我们通过密度泛函理论计算，提出了一种超硬导电的 sp$^{2}$-sp$^{3}$ 混合杂化碳同素异形体。所提出的碳相在具有 \emph{Pmmm} 对称性的正交单胞中含有 36 个原子。在目前的结构（即 poC$_{36}$）中，sp$^{2}$ 键被包裹在 sp$^{3}$ 键网络内部。在 0 GPa 压力下，它比富勒烯 C$_{60}$、石墨烯、Orth-C$_{10}$、orth-C$^{`}_{10}$、oC$_{36}$、C$_{48}$、C20-sc、C21-sc、M-碳、W-碳等更具有动态稳定性和能量优势。在 47.2 GPa 压力下，它的能量比石墨低。维氏硬度值为 76.32 GPa，高于第二硬的材料立方氮化硼。在 0 GPa 压力下，它是一种间接带隙半导体，带隙为 0.08 eV。在大约 11 GPa 的压力下，价带与导带交叉，在 poC$_{36}$ 中产生一维导电性。这些有趣的特性使 poC$_{36}$ 成为机械工具和电子设备的有用材料。拉曼光谱显示了一个类似钻石的波段，以及类似石墨的 G 波段和 D 波段，所有这些波段都随着压力的增加而右移，表明其结构发生了变化。0 GPa 时的 X 射线衍射与金刚石相似，但在 47 GPa 时，四个峰消失了，同时出现了六个新峰，这表明在高压下结构发生了重大变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Electronic Structure

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