稀土掺杂CdTe太阳电池背接触层ZnTe的第一性原理研究

结合CdS/CdTe太阳电池背接触层的制备要求考虑, 利用基于密度泛函理论平面波超软赝势方法和广义梯度近似, 计算了未掺杂ZnTe、稀土Y、Gd掺杂ZnTe的能带和电子态密度, 得到了不同体系下系统总能和晶格常数. 研究表明, 稀土Y和Gd掺杂后ZnTe结构的稳定性均提高, 掺杂Y使ZnTe与CdTe的晶格匹配更好. 计算表明, 掺杂可使载流子发生简并, 掺Y比掺Gd电子有效质量小, 掺Y与掺Gd的载流子浓度数量级相同. 根据计算结果分析了稀土掺杂对ZnTe背接触层的影响. 关键词： ZnTe 稀土掺杂 第一性原理 太阳电池背接触层     

CdTe太阳电池中起因于Cu的深能级

在CdTe太阳电池中,易引入并形成Cu深能级中心. 本文采用深能级瞬态谱测试法研究了ZnTe背接触和石墨背接触CdTe太阳电池的部分深能级中心. 研究中运用密度泛函相关理论,分析闪锌矿结构CdTe,Cd空位体系和掺Cu体系的电子态密度,计算得出T_d场和C_3v场下Cu²⁺ d轨道的分裂情况. 计算结果表明,CdTe太阳电池中的E_v+0206 eV和E_v+0122 eV两个深中心来源于Cu替代Cd原子. 计算结果还表明,掺入Cu可降低CdTe体系能量. 关键词： 深能级瞬态谱 第一性原理 CdTe Cu杂质     

掺杂ZnTe对电子结构与磁性质的影响

为了研究Mn、Fe、Co、Ni掺杂ZnTe的电子结构和磁性的相关性质.本文基于第一性原理的数值基组的方法计算了Mn、Fe、Co、Ni掺杂ZnTe的能带结构、态密度,分析了掺杂结构的稳定性和磁性性质.结果发现Mn、Fe、Co、Ni掺杂ZnTe的杂质替换能分别为-1.14 e V,-1.23 e V,39.95 e V,-4.32 eV,表明Mn、Fe、Ni掺杂的ZnTe在实验上较容易实现.Mn、Co掺杂ZnTe导致体系产生的总磁矩分别为0.997μB,1.103μB,其中磁性的主要来源于Mn、Co原子在Zn位的取代而引起,产生局域磁性主要取决于Mn、Co的d轨道与Te的p轨道耦合作用.     

高压下ZnTe的电子结构和光电性质

应用第一性原理平面波赝势计算方法,研究了闪锌矿ZnTe晶体在外界压力下的电子结构和光电性质,并计算了介电函数和光学吸收系数随压力的变化情况。结果表明:在高压作用下,Te原子和Zn原子的态密度分布都向低能量方向移动,分布范围增大,Te 5p和Zn3d电子轨道杂化变强。随着压力的增大,直接带隙逐渐增大,而间接带隙逐渐变小。当压力为10.7GPa时,能带结构从直接带隙转变为间接带隙结构。压力增大,有利于Te 5p与Zn3d电子间的跃迁,光吸收系数增大,产生更多的电子-空穴对,材料导电能力增强。     

高压下ZnSe的电子结构和光学性质

运用密度泛函理论体系下的平面波赝势(PWP)和广义梯度近似(GGA)方法,利用第一性原理计算了不同的压强下ZnSe晶体闪锌矿结构,得到了它的平衡晶格常数、总能量、电子态密度分布、能带结构、光反射与吸收系数等性质,详细讨论了高压下ZnSe的电子结构,并且结合实验结果定性地分析了高压下的光学性质. 关键词： 闪锌矿结构 态密度 能带结构 密度泛函理论     

闪锌矿GaN弹性性质、电子结构和光学性质外压力效应的理论研究

采用基于密度泛函理论(DFT)的第一性原理平面波赝势方法,结合广义梯度近似(GGA)下的RPBE和局域密度近似(LDA)的CA-PZ交换-关联泛函对闪锌矿结构的GaN在高压的性质进行了系统研究. 计算结果表明:弹性常数、体模量、杨氏模量和能隙都具有明显的外压力效应,计算结果与实验值和理论值很好的符合. 同时利用计算的能带结构和态密度系统分析了GaN的介电函数、折射率、反射率、吸收系数和能量损失函数等光学性质及其外压力效应. 分析结果为GaN的设计与应用提供了理论依据. 关键词： 第一性原理计算 电子结构 光学性质 闪锌矿GaN     

第一性原理研究闪锌矿结构MnSb和MnBi半金属性和磁性的稳定性

采用基于第一性原理的全势能线性缀加平面波方法对闪锌矿结构MnSb和MnBi的电子结构进行自旋极化计算.闪锌矿结构MnSb和MnBi处于晶格平衡时都是半金属性的,并且它们自旋向下电子能带带隙分别是1.32 eV和1.27 eV.闪锌矿结构MnSb和MnBi的自旋总磁矩都为4.00μB/formula,总磁矩主要来源于Mn的原子磁矩,Sb和Bi的原子磁矩对总磁矩的贡献很小而且为负值,它们具有明显的铁磁性特征.使晶体晶格在±10％的范围内发生各向同性形变,对闪锌矿结构MnSb和MnBi的电子结构进行计算.计算结果表明,当晶格各向同性形变分别为-1％～10％和-4％～10％时,闪锌矿结构MnSb和MnBi仍然保持半金属铁磁性,并且总磁矩都稳定于4.00μs/formula.     

第一性原理研究闪锌矿结构MnSb和MnBi半金属性和磁性的稳定性

采用基于第一性原理的全势能线性缀加平面波方法对闪锌矿结构MnSb和MnBi的电子结构进行自旋极化计算。闪锌矿结构MnSb和MnBi处于晶格平衡时都是半金属性的,并且它们自旋向下电子能带带隙分别是1.32eV 和1.27eV。闪锌矿结构MnSb和MnBi的自旋总磁矩都为4.00μB/formula,总磁矩主要来源于Mn的原子磁矩,Sb和Bi的原子磁矩对总磁矩的贡献很小而且为负值,它们具有明显的铁磁性特征. 使晶体晶格在±10%的范围内发生各向同性形变,对闪锌矿结构MnSb和MnBi的电子结构进行计算. 计算结果表明,当晶格各向同性形变分别为-1 % ~ 10 %和-4 % ~10 %时,闪锌矿结构MnSb和MnBi仍然保持半金属铁磁性,并且总磁矩都稳定于4.00μB/formula.     

第一性原理研究闪锌矿结构MnSb和MnBi半金属性和磁性的稳定性

采用基于第一性原理的全势能线性缀加平面波方法对闪锌矿结构MnSb和MnBi的电子结构进行自旋极化计算。闪锌矿结构MnSb和MnBi处于晶格平衡时都是半金属性的,并且它们自旋向下电子能带带隙分别是1.32eV 和1.27eV。闪锌矿结构MnSb和MnBi的自旋总磁矩都为4.00μB/formula,总磁矩主要来源于Mn的原子磁矩,Sb和Bi的原子磁矩对总磁矩的贡献很小而且为负值,它们具有明显的铁磁性特征. 使晶体晶格在±10%的范围内发生各向同性形变,对闪锌矿结构MnSb和MnBi的电子结构进行计算. 计算结果表明,当晶格各向同性形变分别为-1 % ~ 10 %和-4 % ~10 %时,闪锌矿结构MnSb和MnBi仍然保持半金属铁磁性,并且总磁矩都稳定于4.00μB/formula.     

ZnTe(110)表面电子态及其弛豫对表面电子态的影响

给出了Ⅱ-Ⅵ族半导体化合物ZnTe(110)表面电子特性的理论研究.考虑最近邻的sp³s模型描述体态电子结构，使用散射理论方法，给出了理想和弛豫ZnTe(110)表面的波矢分辨的电子态密度和表面投影带结构.结果表明：弛豫的ZnTe(110)表面在带隙中没有表面态存在.在价带中的表面态及表面共振态和其他弛豫的Ⅲ-Ⅴ族及Ⅱ-Ⅵ族半导体的(110)表面具有相似的特征.与实验结果及第一性原理的自洽赝势计算结果相比，计算的结果符合得很好. 关键词：     

First-principles investigation of electronic structure,effective carrier masses,and optical properties of ferromagnetic semiconductor CdCr_2S_4

The electronic structures, the effective masses, and optical properties of spinel CdCr_2S_4 are studied by using the fullpotential linearized augmented planewave method and a modified Becke–Johnson exchange functional within the densityfunctional theory. Most importantly, the effects of the spin–orbit coupling(SOC) on the electronic structures and carrier effective masses are investigated. The calculated band structure shows a direct band gap. The electronic effective mass and the hole effective mass are analytically determined by reproducing the calculated band structures near the BZ center.SOC substantially changes the valence band top and the hole effective masses. In addition, we calculated the corresponding optical properties of the spinel structure CdCr_2S_4. These should be useful to deeply understand spinel CdCr_2S_4 as a ferromagnetic semiconductor for possible semiconductor spintronic applications.     

First-principle study of the electronic and optical properties of BInGaAs quaternary alloy lattice-matched to GaAs

The first-principle calculations based on density functional theory have been used to study the electronic and optical properties of zinc-blende BInGaAs quaternary alloy lattice-matched to GaAs. The calculated results show the band gap of BInGaAs alloy are direct and the band gap will reduce with the increment of boron and indium composition. The electronic structures of BInGaAs alloy are analyzed via the calculation of density of states. The variation of optical properties including dielectric function, absorption coefficient, reflectivity, refractive index and energy loss function of the alloy were also investigated in detail.     

Direct observation of the mass renormalization in SrVO3 by angle resolved photoemission spectroscopy

Band dispersions and Fermi surfaces of the three-dimensional Mott-Hubbard system SrVO3 are directly observed by angle-resolved photoemission spectroscopy. An observed spectral weight distribution near the Fermi level (E(F)) shows cylindrical Fermi surfaces as predicted by band-structure calculations. By comparing the experimental results with calculated surface electronic structures, we conclude that the obtained band dispersion reflects the bulk electronic structure. The enhanced effective electron mass obtained from the energy band near E(F) is consistent with the bulk thermodynamic properties and hence with the normal Fermi-liquid behavior of SrVO3.     

The stability and electronic properties of wurtzite and zinc-blende ZnS nanowires

The stability and electronic properties of the pristine wurtzite (WZ) and zinc-blende (ZB) structural ZnS nanowires are investigated and compared by using first-principles approaches. It shows that the WZ-ZnS nanowire is more stable energetically than the ZB-ZnS nanowire. The two kinds of ZnS nanowires have different electronic properties due to both the quantum confinement effect and the surface effect. The band gaps of pristine WZ nanowires become larger than that of the corresponding bulk ZnS, while those of ZB nanowires are smaller. The electronic properties of the hydrogen-passivated WZ-ZnS and ZB-ZnS nanowires are further calculated. The underlying physical reason for their energetic and electronic structures is elucidated.     

Theoretical characterization of carrier compensation in P-doped diamond

Based on the electron-hole recombination ratio (the number of electron-hole recombination in unit time and volume), we have examined several P complexes surrounded with vacancy (V) or H to explore the effect of carrier compensation on the electronic properties in P-doped diamond by first-principle calculations. Our calculated results show that the monovacancy complex P-V-H is not a valid recombination center in P-doped diamond, in which case electron cannot be recombined and thus donor cannot be compensated. However, the level in the band gap introduced by the divacancy complex P-2V-2H is a valid recombination center, which accelerates the electron-hole recombination at high ratio. For the trivacancy complex P-3V, three levels are introduced near the middle of the band gap, which may serve as more valid recombination centers than others. In this case, the electron-hole recombination ratio enhances successively, namely, the compensator density increases continuously too. In addition, the electronic properties of the P-related complexes in negative charge states are similar with those of neutral charge states. The study may explain well the experimental results and be useful for the further experiment research.     

First-principles study of zinc-blende to rocksalt phase transition in BN

The structural, electronic and elastic properties of the cubic boron nitride (BN) compound are investigated by a first-principle pseudopotential method. The calculations show that the structural phase transition from the zinc-blende(ZB) structure to the rocksalt (RS) structure occurs at a transition pressure of 1088 GPa and with a volume reduction of 3.1%. Both the ZB and RS structures of BN have indirect gaps, with energy gaps of 4.80 eV and 2.11 eV, respectively. The positive pressure derivative of the indirect band gap (Γ-X) energy for the the ZB phase and the predicted ultrahigh metallization pressure are attributed to the absence of d occupations in the valence bands. The increase of the shear modulus with increasing pressure implies that the lattice stability becomes higher when BN is compressed.     

Electronic Structure and Magnetic Properties of Cr-Doped AlN

To understand the electronic and magnetic properties, we have studied Cr-doped zinc-blende AlN system in detail by applying a first-principle plane wave pseudopotential method based on the density functional theory within the local spin density approximation. The analyses of the band structures, density of states, exchange interactions, and magnetic moments show that Al1-xCrxN alloys may exhibit a half-metallic ferromagnetism character, that Cr in the diluted doping limit forms near-midgap deep levels, and that the total magnetization of the cell is 3μB per Cr atom, which does not change with Cr concentration. Moreover, we have succeeded in predicting that Al1-xCrzN alloys in x = 0.0625 has a very high Curie temperature, and lind that ferromagnetic exchange interaction between magnetic dopants is short-ranged.     

Structural, electronic, and magnetic properties of Co-doped ZnO

Density functional theory based calculations have been carried out to study structural, electronic, and magnetic properties of Zn1-xCoxO (x = 0, 0.25, 0.50, 0.75) in the zinc-blende phase, and the generalized gradient approximation proposed by Wu and Cohen has been used. Our calculated lattice constants decrease while the bulk moduli increase with the increase of Co 2+ concentration. The calculated spin polarized band structures show the metallic behavior of Co-doped ZnO for both the up and the down spin cases with various doping concentrations. Moreover, the electron population is found to shift from the Zn-O bond to the Co-O bond with the increase of Co 2+ concentration. The total magnetic moment, the interstitial magnetic moment, the valence and the conduction band edge spin splitting energies, and the exchange constants decrease, while the local magnetic moments of Zn, Co, O, the exchange spin splitting energies, and crystal field splitting energies increase with the increase of dopant concentration.     

Electronic structures of the zinc-blende GaN/Ga1−xAlxN compressively strained superlattices and quantum wells

The electronic structures of the zinc-blende GaN/Ga_0.85Al_0.15N compressively strained superlattices and quantum wells are investigated using a 6×6 Hamiltonian model (including the heavy hole, light hole and spin-orbit splitting band). The energy bands, wavefunctions and optical transition matrix elements are calculated. It is found that the light hole couples with the spin-orbit splitting state even at thek=0 point, resulting in the hybrid states. The heavy hole remains a pure heavy hole state atk=0. The optical transitions from the hybrid valence states to the conduction states are determined by the transitions of the light hole and spin-orbit splitting states to the conduction states. The transitions from the heavy hole, light hole and spin-orbit splitting states to the conduction states obey the selection rule Δn=0. The band structures obtained in this work will be valuable in designing GaN/GaAlN based optoelectronic devices.