点缺陷对单层MoS2电子结构及光学性质的影响研究

采用基于第一性原理的贋势平面波方法,对不同类型点缺陷单层MoS2电子结构、能带结构、态密度和光学性质进行计算。计算结果表明：单层MoS2属于直接带隙半导体,禁带宽度为1.749ev,V-Mo缺陷的存在使得MoS2转化为间接带隙Eg=0.671eV的p型半导体,V-S缺陷MoS2的带隙变窄为Eg=0.974eV,S-Mo缺陷的存在使得MoS2转化为间接带隙Eg=0.482eV; Mo-S缺陷形成Eg=0.969eV直接带隙半导体,费米能级上移靠近价带。 费米能级附近的电子态密度主要由Mo的4d态和s的3p态电子贡献。光学性质计算表明：空位缺陷对MoS2的光学性质影响最为显著,可以增大MoS2的静态介电常数、折射率n0和反射率,降低吸收系数和能量损失。     

畸形钙钛矿DyMnO3电子结构与光学性质的第一性原理研究

基于密度泛函理论的广义梯度近似对畸形钙钛矿DyMnO₃的基态电子结构及光学性质进行计算和分析.结果表明优化的晶体结构参数与实验结果相符合,DyMnO₃具有非间接带隙大小为0.91 eV的能带结构,结合态密度分析了各元素价电子态的分布.计算分析包括介电常数,吸收系数,反射率等光学性质.     

锰掺杂二硅化铬电子结构和光学性质的第一性原理计算

采用基于第一性原理的密度泛函理论(DFT)赝势平面波方法计算了锰掺杂二硅化铬(CrSi2)体系的能带结构、态密度和光学性件质.计算结果表明末掺杂CrSi2属于间接带隙半导体间接带隙宽度△ER=0.35 eV;Mn掺杂后费米能级进入导带,带隙变窄,且间接带隙宽度△Eg=0.24 eV,CrSi2转变为n型半导体.光学参数发生改变,静态介电常数由掺杂前的ε1(O)=32变为掺杂后的ε1(O)=58;进一步分析了掺杂对CrSi2的能带结构、态密度和光学性质的影响,为CrSi2材料掺杂改件的研究提供r理论依据.     

0.5NdAlO3-0.5CaTiO3电子结构及光学性质的第一性原理计算

采用基于第一性原理密度泛函理论的平面波赝势方法,对0.5NdAlO₃-0.5CaTiO₃晶体进行结构优化,并对其能带结构,态密度和光学性质进行了理论计算.结构优化后晶格参数与实验数据相符合,误差小于1%;能带计算结果表明0.5NdAlO₃-0.5CaTiO₃为间接带隙,带隙值为0.52eV;费米面附近的能带由Nd-4f,O-2p,Nd-4p,Al-3p,Ti-4d层的电子态密度确定.同时也计算了该结构的介电函数,反射率和复折射率等光学性质.     

单斜BiScO_3和BiCrO_3的电子结构和光学性质的第一性原理比较研究

采用基于密度泛函理论的第一性原理赝势平面波方法,对单斜BiScO_3和BiCrO_3的电子结构和光学性质进行了比较研究.结果表明:BiScO_3为无磁绝缘体,带隙为直接带隙,BiCrO_3为间接带隙磁性半导体;BiScO_3和BiCrO_3都不吸收能量小于1.02 eV的光子,BiScO_3吸收可见光的能力强于BiCrO_3.     

单斜BiScO3和BiCrO3的电子结构和光学性质的第一性原理比较研究

采用基于密度泛函理论的第一性原理赝势平面波方法,对单斜BiScO3和BiCrO3的电子结构和光学性质进行了比较研究。结果表明：BiScO3为无磁绝缘体,带隙为直接带隙,BiCrO3为间接带隙磁性半导体;BiScO3和BiCrO3都不吸收能量小于1.02 eV的光子,BiScO3吸收可见光的能力强于BiCrO3。     

Rb吸附石墨烯纳米带电子性质和光学性质的研究

本文基于密度泛函理论的第一性原理方法了计算了Rb、O和H吸附石墨烯纳米带的差分电荷密度、能带结构、分波态密度和介电函数，调制了石墨烯纳米带的电子性质和光学性质，给出了不同杂质影响材料光学特性的规律.结果表明本征石墨烯纳米带为n型直接带隙半导体且带隙值为0.639 eV；Rb原子吸附石墨烯纳米带之后变为n型简并直接带隙半导体，带隙值为0.494eV；Rb和O吸附石墨烯纳米带变为p型简并直接带隙半导体，带隙值增加为0.996eV；增加H吸附石墨烯纳米带后，半导体类型变为n型直接带隙半导体，且带隙变为0.299eV，带隙值相对减小，更有利于半导体发光器件制备.吸附Rb、O和H原子后，石墨烯纳米带中电荷密度发生转移，导致C、Rb、O和H之间成键作用显著.吸附Rb之后，在费米能级附近由C-2p、Rb-5s贡献；增加O原子吸附之后，O-2p在费米能级附近贡献非常活跃，杂化效应使费米能级分裂出一条能带；再增加H原子吸附之后，Rb-4p贡献发生蓝移，O-2p在费米能级附近贡献非常强，费米能级分裂出两条能带.Rb、O和H的吸附后，明显调制了石墨烯纳米带的光学性质.     

Cd、Sr掺杂Mg2Ge电子结构和光学性质的第一性原理研究

此文用基于密度泛函理论(DFT)的第一性原理计算方法,分别研究了本征、掺Cd、掺Sr的Mg₂Ge的能带结构、电子态密度和光学性质.研究结果表明,本征Mg₂Ge是一种间接带隙半导体,带隙值为0.228eV.Sr的掺入使其变成带隙为0.591 eV的直接带隙半导体,Cd掺杂Mg₂Ge后表现出半金属性质.掺杂后的主要吸收峰减小,吸收谱范围增加.在可见光能量范围内,掺杂的Mg₂Ge有更低的反射率,对可见光的利用率增强.此外,掺杂还提高了高能区的光电导率.     

应变和电场对Ga2SeTe/In2Se3异质结电子结构和光学性质的影响

异质结构的构筑与堆垛是新型二维材料物性调控及应用的有效策略.基于密度泛函理论的第一性原理计算,本文研究了4种不同堆叠构型的新型二维Janus Ga₂SeTe/In₂Se₃范德瓦耳斯异质结的电子结构和光学性质. 4种异质结构型均为Ⅱ型能带结构的间接带隙半导体,光致电子的供体和受体材料由二维In₂Se₃的极化方向决定.光吸收度在可见光区域高达25%,有利于太阳可见光的有效利用.双轴应变可诱导直接-间接带隙转变,外加电场能有效调控异质结构带隙,使AA2叠加构型的带隙从0.195 eV单调增大到0.714 eV,AB2叠加构型的带隙从0.859 eV单调减小到0.058 eV,两种调控作用下异质结的能带始终保持Ⅱ型结构.压缩应变作用下的异质结在波长较短的可见光区域表现出更优异的光吸收能力.这些研究结果揭示了Janus Ga₂SeTe/In₂Se₃范德瓦耳斯异质结电子结构的调控机理,为新型光电器件的设计提供理论指导.     

畸形钙钛矿DyMnO_3电子结构与光学性质的第一性原理研究（英文）

基于密度泛函理论的广义梯度近似对畸形钙钛矿DyMnO_3的基态电子结构及光学性质进行计算和分析.结果表明优化的晶体结构参数与实验结果相符合,DyMnO_3具有非间接带隙大小为0.91 e V的能带结构,结合态密度分析了各元素价电子态的分布.计算分析包括介电常数,吸收系数,反射率等光学性质.     

Theoretical investigation of Cu-containing materials with different valence structure types: BaCu2S2, Li2CuSb,and LiCuS

Optoelectronics research requires cheap materials with a broad spectrum of optical, electronic, and structural properties. The class of Heusler compounds and ternary structures provide many possibilities for finding alternative group IV and III–V semiconductor compounds. This study introduces wider band gap materials for use in solar cells as an alternative to cadmium sulfide buffer layers. The buffer layer is inserted between the absorber layer (p-type) and the transparent window layer (n-type) to enhance the maximum amount of light transmission. Reasonable calculations are reported for the band gaps of copper-containing materials: LiCuS, BaCu₂S₂, and Li₂CuSb. Previous optical analysis measurements of these films determined that the band gaps were 1.8 and 1.9 eV for BaCu₂S₂ and LiCuS, respectively. In general, semiconductor compounds have been studied theoretically, but there are major differences between the experimental and theoretically calculated band gaps. A suitable calculation method for semiconductor compounds is described in this study. For the first time, calculations based on the Engel and Vosko method are introduced for these semiconductor compounds. This method yields band gaps that are comparable to the experimental values, which facilitate the development of microscopic analyses of these compounds. Direct band gaps of 1.15 and 1.7 eV were obtained for BaCu₂S₂ and LiCuS, respectively, whereas the indirect band gap was 0.7 eV for Li₂CuSb.     

First-principles calculations of structural, electronic, optical and elastic properties of magnesite MgCO3 and calcite CaCO3

Detailed ab initio calculations of the structural, electronic, optical and elastic properties of two crystals - magnesite (MgCO₃) and calcite (CaCO₃) - are reported in the present paper. Both compounds are important natural minerals, playing an important role in the carbon dioxide cycling. The optimized crystal structures, band gaps, density of states diagrams, elastic constants, optical absorption spectra and refractive indexes dependence on the wavelength all have been calculated and compared, when available, with literature data. Both crystals are indirect band compounds, with calculated band gaps of 5.08 eV for MgCO₃ and 5.023 eV for CaCO₃. Both values are underestimated by approximately 1.0 eV with respect to the experimental data. Although both crystals have the same structure, substitution of Mg by Ca ions leads to certain differences, which manifest themselves in noticeable change in the electronic bands profiles and widths, shape of the calculated absorption spectra, and values of the elastic constants. Response of both crystals to the applied hydrostatic pressure was analyzed in the pressure range of phase stability, variations of the lattice parameters and characteristic interionic distances were considered. The obtained dependencies of lattice constants and calculated band gap on pressure can be used for prediction of properties of these two hosts at elevated pressures that occur in the Earth's mantle.     

First-principles study of electronic structure and optical properties of barium strontium titanates (BaxSr1−xTiO3)

Using first-principles calculations based on density-functional theory in its local-density approximation, we investigate the energy band structures and total density of states (TDOS) of barium strontium titanates (BSTs). Direct band gaps of 1.89 and 1.87 eV at the Γ point in the Brillouin zone are calculated for Ba_xSr_1−xTiO₃ (x = 2/3 and 1/3), respectively. The optical properties of the above perovskites in the core-level spectra are investigated by the first-principles under scissor approximation. The real and imaginary parts of the complex dielectric function and derive optical constants, viz., the refractive index, extinction coefficient, reflectivity, and the electron energy-loss spectrum are calculated.     

BaZr0.5Ti0.5O3电子结构、力学和光学性质的第一性原理研究

在广义梯度近似（GGA）下,采用基于密度泛函理论的第一性原理方法对BaZr0.5Ti0.5O3的电子结构、力学性质和光学性质进行了理论计算．计算得到该晶体的晶格常数为4.145925 Å,且此材料是一种间隙的半导体材料,价带和导带都来源于Ba原子、O原子的p态和Ti原子、Zr原子的d态电子间的杂化;力学性质的计算得到：BaZrO3和BaZr0.5Ti0.5O3的晶体结构稳定,且BaZrO3晶体掺杂Ti元素后体系的硬度变大;光学计算结果表明BaZr0.5Ti0.5O3的静态介电常数为4.20,吸收主要集中在低能区,静态折射率为2.00,能量损失峰出现在11.59eV处．上述研究结果为BaZr0.5Ti0.5O3材料的设计和应用提供了理论依据．     

BaZr0.5Ti0.5O3电子结构、力学和光学性质的第一性原理研究

在广义梯度近似（GGA）下,采用基于密度泛函理论的第一性原理方法对BaZr0.5Ti0.5O3的电子结构、力学性质和光学性质进行了理论计算．计算得到该晶体的晶格常数为4.145925 Å,且此材料是一种间隙的半导体材料,价带和导带都来源于Ba原子、O原子的p态和Ti原子、Zr原子的d态电子间的杂化;力学性质的计算得到：BaZrO3和BaZr0.5Ti0.5O3的晶体结构稳定,且BaZrO3晶体掺杂Ti元素后体系的硬度变大;光学计算结果表明BaZr0.5Ti0.5O3的静态介电常数为4.20,吸收主要集中在低能区,静态折射率为2.00,能量损失峰出现在11.59eV处．上述研究结果为BaZr0.5Ti0.5O3材料的设计和应用提供了理论依据．     

Structural, electronic and optical properties of orthorhombic distorted perovskite TbMnO3

This paper calculates the structural parameters, electronic and optical properties of orthorhombic distorted perovskite-type TbMnO3 by first principles using density functional theory within the generalised gradient approximation. The calculated equilibrium lattice constants are in a reasonable agreement with theoretical and experimental data. The energy band structure, density of states and partial density of states of elements are obtained. Band structures show that TbMnO3 is an indirect band gap between the O 2p states and Mn 3d states, and the band gap is of 0.48 eV agreeing with experimental result. Furthermore, the optical properties, including the dielectric function, absorption coefficient, optical reflectivity, refractive index and energy loss spectrum are calculated and analysed, showing that the TbMnO3 is a promising dielectric material.     

第一性原理研究B掺杂Mn_4Si_7的电子结构和光学性质

采用基于密度泛函理论的第一性原理计算方法,对未掺杂及B掺杂Mn_4Si_7的电子结构和光学性质进行理论计算.研究结果表明,未掺杂Mn_4Si_7是间接带隙半导体,其禁带宽度为0.786 eV,B掺杂后其禁带宽度下降为0.723 eV. B掺杂Mn_4Si_7是p型半导体材料.未掺杂Mn_4Si_7在近红外区的吸收系数达到10~5 cm~(-1),B掺杂引起Mn_4Si_7的折射率、吸收系数、反射系数及光电导率增加.     

Tunable electronic and optical properties of GaS/GaSe van der Waals heterostructure

We have used first-principles calculations to investigate the electronic and optical properties of GaS/GaSe van der Waals heterostructures formed by stacking two-dimensional GaSe and GaSe monolayers. Our findings confirm that the GaS/GaSe heterostructures transform from an indirect to a direct band gap material for the two stackings considered in this study. In addition, we found that the direct band gaps are 1.780 eV and 1.736 eV for AA and AB stacking, respectively. It is observed that the behavior of the optical properties of AA stacking is similar to AB stacking with some differences in details and both heterostructures located in UV range. The refractive index values are 2.21 (AA pattern) and 2.18 (AB pattern) at zero photon energy limit and increase to 2.937 for AA and 2.18 AB patterns and both located in the visible region. More importantly, the GaS/GaSe heterostructures have a variety of extraordinary electronic and optical properties. Accordingly, these heterostructures can be useful for the solar cell, nanoelectronics, and optoelectronic applications.     

First-principles study on the electronic and optical properties of BiFeO3

The structural, electronic, and optical properties of multiferroic bismuth ferrite (BiFeO₃) are investigated using density functional theory within generalized gradient approximation (GGA). The calculated lattice parameters are in good agreement with the experimental data. The electronic structure shows that BiFeO₃ has an indirect (very close to direct) band gap of 1.06 eV. The complex dielectric function, absorption spectra, refractive index, extinction coefficient, energy-loss spectrum and reflectivity are calculated, and the results are compared with the available experimental data. Finally, the optical properties of BiFeO₃ are discussed based on the band structure calculations.