Na, Mg和Al取代氧化锌纳米管的电子和光学性质:一项深入的DFT研究

Md Shahzad Khan, H. Howari, Z. Khan, M. Imran, Mohd. Shakir
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引用次数: 0

摘要

本文研究了基于dft的原始和金属(M = Na, Mg和Al)取代氧化锌纳米管(M- znont)的理论研究。研究表明,Zn分别被Na、Mg和Al取代后,ZnONT的电子能带隙发生了变化。Na加入后禁能隙消失,而Al取代后禁能隙达到0.08eV。地层能计算表明这些金属取代的可行性,其中Na的掺入是最有利的。偏态密度(PDOS)分析与能带结构密切相关。Al-3p在Al-ZnONT中贡献的高于费米能级的定域态表明Al-ZnONT对进入的亲核试剂具有电子亲和力。我们的光学研究表明,M-ZnONT在远红外(IR)和可见光(Vis)区域的ε1(ω)值很大。因此,表明在规定的范围内,金属取代的ZnONTs具有较高的折射率。研究表明,由于衰减、弯曲和吸收引起的光子能量损失在紫外(UV)和远紫外(3eV至8eV)区域较弱。然而,对于各自的能量范围,预测高反射率。这表明纳米管是一种很好的反射器,用于高反射要求的涂层材料表面。用DFT方法寻找功能化ZnONT的电子和光学性质。所有的计算都是在密度泛函理论(DFT)的框架下使用Troullier Martins的范数守恒伪势进行的。金属在ZnONT表面的掺入导致M-ZnONT在远红外和可见光区域有强烈的ε1(ω)值。研究表明,金属取代纳米管是一种很好的反射器,适用于要求高反射的涂层材料表面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electronic and optical properties of Na, Mg, and Al substituted Zinc-oxide Nanotube: An insight DFT study
The present work deals with DFT-based theoretical investigations on pristine and metal (M = Na, Mg, and Al) substituted zinc oxide nanotube (M-ZnONT). The investigation advocates a change in the electronic bandgap of ZnONT on the respective substitution of Zn with Na, Mg, and Al. The forbidden energy gap vanishes on Na incorporation, while Al substitution brings the gap to 0.08eV. The formation energy calculations suggest the feasibility of these metallic substitutions, of which Na incorporation is most favorable. Partial density of state (PDOS) analysis is well correlated with band structures. A localized state above the Fermi level contributed from Al-3p in Al-ZnONT suggests the electronic affinity of Al-ZnONT for incoming nucleophiles. Our optical investigation shows large ε1(ω) values in far-infrared (IR) and visible (Vis) regions for M-ZnONT. Hence, suggests a high refractive index for the metal-substituted ZnONTs in the prescribed range. The study suggests that photonic energy loss due to attenuation, bending, and absorption are weak in ultra-violet (UV) and far UV regions i.e, (3eV to 8eV). However, for the respective energy range, high reflectivity is predicted. This indicates the nanotubes as a good reflector for the purpose of coating material surfaces where high reflection is demanded. Finding electronic and optical properties of functionalized ZnONT using DFT method. All calculations have been performed in the framework of density functional theory (DFT) using Troullier Martins’s norm-conserving pseudo-potential. Metal incorporation at the surface of ZnONT consequent intense ε1(ω) values in far infra-red and visible regions for M-ZnONT. The investigation suggests that the metal-substituted nanotube is a good reflector for coating material surfaces where high reflection is demanded.
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来源期刊
Current Materials Science
Current Materials Science Materials Science-Materials Science (all)
CiteScore
0.80
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0.00%
发文量
38
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