应力调控对单层TiOCl2电子结构及光学性质的影响

基于密度泛函理论的第一性原理计算,对单层TiOCl₂的电子结构、输运性质和光学性质进行了理论研究.对单层TiOCl₂材料的声子谱、分子动力学和弹性常数的计算结果表明,该材料在常温下能稳定存在,并具有较好的动力学、热力学和机械稳定性.电子结构分析表明,单层TiOCl₂是一种间接窄带隙半导体(能隙为1.92 eV).在应力调控下,单层TiOCl₂材料的能带结构、输运性质和光学性质均发生明显变化.沿a方向施加-4%的收缩应力后,单层TiOCl₂由间接带隙变为直接带隙,带隙减小至1.66 eV.同时TiOCl₂还表现出明显的各向异性特征,电子沿b方向传输(迁移率约为803 cm~2·V^-1·s^-1),空穴则沿a方向传输(迁移率约为2537 cm~2·V^-1·s^-1).此外,施加收缩应力还会使单层TiOCl₂材料的光吸收率、反射率和透射率的波峰(谷)发生红移...     

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.     

(BiFeO3)25/(La0.7Sr0.3MnO3)25 多层膜的光学和电学性质

采用射频磁控溅射方法在(001)SrTiO₃衬底上制备(001)取向的(BiFeO₃)₂₅/(La_0.7Sr_0.3MnO₃)₂₅多层膜.光学测试结果表明,1.3-2.1 eV范围内,相对于衬底而言多层膜光吸收增强; BiFeO₃的带隙为2.7 eV. 另外,结合绝缘介质导电模型分析了所测得的电流-电压数据,在所测试的温度及电压下,所制备的(BiFeO₃)₂₅/(La_0.7Sr_0.3MnO₃)₂₅多层膜的导电机理由空间电荷限制电导主导. 关键词： 多层膜 吸光度 空间电荷限制电导     

空间用GaInP/GaAs/In0.3Ga0.7 As(1 eV)倒装三结太阳电池研制

采用阶变缓冲层技术 (step-graded) 外延生长了具有更优带隙组合的倒装GaInP/GaAs/In_0.3Ga_0.7As(1.0 eV) 三结太阳电池材料, TEM和HRXRD测试表明晶格失配度为2%的In_0.3Ga_0.7As 底电池具有较低的穿透位错密度和较高的晶体质量, 达到太阳电池的制备要求. 通过键合、剥离等工艺制备了太阳电池芯片. 面积为 10.922 cm² 的太阳电池芯片在空间光谱条件下转换效率达到32.64% (AM0, 25 ℃), 比传统晶格匹配的 GaInP/GaAs/Ge(0.67 eV) 三结太阳电池的转换效率提高3个百分点. 关键词： 太阳电池 三结 倒装结构     

单层MoSe2单晶的光学及电学性能探究

采用Au箔作为生长衬底,通过化学气相沉积法制备了高质量的单层MoSe₂单晶.通过光学显微镜、扫描电子显微镜、扫描透射电子显微镜等对其形貌和结构进行了表征,研究了单层MoSe₂单晶的光学及电学特性.结果表明：单层MoSe₂具有非线性光学特性,并具有直接带隙结构(带隙宽度约为1.56 eV)及较好的光致发光特性.当其作为场效应晶体管器件的半导体沟道材料时,器件的载流子迁移率为1.6 cm²/(V·s),开关比约为10⁴.     

铁电单晶0.62Pb(Mg1/3Nb2/3)O3-0.38PbTiO3折射率的研究

用最小偏向角法在20℃下精确测量了0.62Pb(Mg_1/3Nb_2/3)O_{3< /sub>-0.38PbTiO3( 0.62PMN-0.38PT)单晶的折射率，给出了该温度下折射率色散的Sellmeier方程.研究了能带 结构与折射率的关系，计算了样品的Sellmeier光学系数：对no，E0=5.50eV,λ0=0.2 26μm，Ｓ０=1.004×10¹⁴m^-2，Ed=28.1 0eV；对ne，Ｅ0=5.57eV,λ 0=0.223μm，S0=1.017×10¹⁴m^-2，Ed=28.10eV.A BO3型钙钛矿材料中，BO6八面体基元决定了晶体的能带结构，对折 射率产生重要影响. 关键词： PMNT单晶 折射率 Sellmeier光学系数}     

类石墨烯硼-磷单层材料的电子与光学性能的第一性原理计算研究

基于第一性原理计算,对硼-磷单层材料的电子结构和光学性质进行系统地理论研究. 全局结构搜索和第一性原理分子动力学模拟现实二维硼-磷单层材料能量最低的结构与石墨烯类似,具有很高的稳定性. 类石墨烯二维硼-磷单层是直接带隙半导体,带隙宽度1.37 eV,其带隙宽度随层数增加而减少. 硼-磷单层的带隙宽度受外界应力影响.硼-磷单层的载流子迁移率达到106 cm2/V. MoS2/BP二维异质结可用于光电器件,其理论光电转换效率为17.7%?19.7%. 表明类石墨烯硼-磷二维材料在纳米电子器件与光电子器件的潜在应用价值.     

(TiO2)12量子环及过渡金属化合物掺杂对其电子性质影响的密度泛函理论研究

本文采用第一性原理中基于密度泛函理论(DFT)的广义梯度近似(GGA)方法, 设计了一种新的(TiO₂)₁₂ 量子环结构, 研究了它的几何结构、平均结合能及电子云分布等属性. 在此新型结构的基础上, 分别采用过渡金属化合物MoS₂, MoSe₂, MoTe₂, WS₂, WSe₂和WTe₂进行掺杂, 并分析了掺杂后体系的几何结构及电子属性(如平均结合能、能级结构、HOMO-LUMO轨道电子云密度分布和电子态密度等). 计算结果表明: (TiO₂)₁₂量子环直径为1.059 nm, 呈中心对称分布, 且所有原子组成一个二维平面结构, 使其几何结构比较稳定, 另外该量子环HOMO-LUMO轨道电子云分布均匀, 且能隙为3.17 eV, 与半导体材料TiO₂晶体的能隙的实验值(3.2 eV)非常接近. 掺杂后量子环的能隙均大幅减小, 其中WTe₂的掺杂结果能隙最小, 仅为0.61 eV, MoTe₂的掺杂结果能隙最大, 为1.16 eV, 也比掺杂前减小约2.0 eV. 其他掺杂结果的能隙都在1 eV左右, 变化不大. 这个能隙的TiO₂可以利用大部分的太阳光能, 使TiO₂具有更为广泛的应用.     

真空紫外光激发下Ce3+、Tb3+激活的BaCa2(BO3)2的发光性质

利用XRD、VUV及UV光谱等方法对Ce³⁺、Tb³⁺离子掺杂以及Ce³⁺、Tb³⁺离子共掺的3种BaCa₂(BO₃)₂荧光粉的相纯度、发光性质、浓度猝灭现象进行研究。结果表明:3种荧光粉在VUV波段有较好的吸收,基质吸收带位于140～190 nm范围。Ce³⁺在BaCa₂(BO₃)₂的最低4f5d跃迁带位置在360 nm附近,其5d→²F_J(J=5/2, 7/2)发射峰分别位于393,424 nm。Tb³⁺掺杂的样品在172 nm激发下的发射光谱由4个窄带组成,分别对应⁵D₄→⁷F_J(J=3,4,5,6)的跃迁,其中占主导位置的是⁵D₄→⁷F₅的跃迁,大约位于543 nm处,主要为绿光发射。在Ce³⁺,Tb³⁺离子共掺杂的BaCa₂(BO₃)₂光谱中,观察到Ce³⁺-Tb³⁺离子间有能量传递。     

含新结构单元[Co3(SS)3(PR3)3]的钴化合物的磁性研究

通过含新结构单元钴化合物:Co₃(bdt)₃(PBu₃)₃(Ⅰ),Co₃(tdt)₃(PBu₃)₃(Ⅱ),[Co₃(bdt)₃(PPh₃)₃][CoBr₃(dmf)](Ⅲ)和[Co₃(edt)₃(PEtB)₃]₂[Co₂Cl₄(Et₂SO₂)₂](Ⅳ)(bdt=1,2-S₂C₆H₄^2-,tdt=4-Me-1,2-S₂C₆H₃^2-,edt=SCH₂CH₂S^2-)的磁极矩和¹H NMR等研究表明:它们均具顺磁性,钴原子之间存在着反铁磁偶合作用,同时还讨论了它们的磁学性质和分子结构之间关系。     

Tuning electronic properties of the S_2/graphene heterojunction by strains from density functional theory

Based on the density functional calculations, the structural and electronic properties of the WS_2/graphene heterojunction under different strains are investigated. The calculated results show that unlike the free mono-layer WS_2, the monolayer WS_2 in the equilibrium WS_2/graphene heterojunctionis characterized by indirect band gap due to the weak van der Waals interaction. The height of the schottky barrier for the WS_2/graphene heterojunction is 0.13 eV, which is lower than the conventional metal/MoS_2 contact. Moreover, the band properties and height of schottky barrier for WS_2/graphene heterojunction can be tuned by strain. It is found that the height of the schottky barrier can be tuned to be near zero under an in-plane compressive strain, and the band gap of the WS_2 in the heterojunction is turned into a direct band gap from the indirect band gap with the increasing schottky barrier height under an in-plane tensile strain. Our calculation results may provide a potential guidance for designing and fabricating the WS_(2~-)based field effect transistors.     

Electronic and optical properties of single-layer MoS<Subscript>2</Subscript>

The electronic structures of a MoS₂ monolayer are investigated with the all-electron first principle calculations based on the density functional theory (DFT) and the spin-orbital couplings (SOCs). Our results show that the monolayer MoS₂ is a direct band gap semiconductor with a band gap of 1.8 eV. The SOCs and d-electrons in Mo play a very significant role in deciding its electronic and optical properties. Moreover, electronic elementary excitations are studied theoretically within the diagrammatic self-consistent field theory. Under random phase approximation, it shows that two branches of plasmon modes can be achieved via the conduction-band transitions due to the SOCs, which are different from the plasmons in a two-dimensional electron gas and graphene owing to the quasi-linear energy dispersion in single-layer MoS₂. Moreover, the strong optical absorption up to 10⁵ cm^-1 and two optical absorption edges I and II can be observed. This study is relevant to the applications of monolayer MoS₂ as an advanced photoelectronic device.     

Formation of a quasi-free-standing graphene with a band gap at the dirac point by Pb atoms intercalation under graphene on Re(0001)

The control of the graphene electronic structure is one of the most important problems in modern condensed matter physics. The graphene monolayer synthesized on the Re(0001) surface and then subjected to the intercalation of Pb atoms is studied by angle-resolved photoelectron spectroscopy and low-energy electron diffraction. The intercalation of Pb atoms under graphene takes place when the substrate is annealed above 500°C. As a result of the intercalation of Pb atoms, graphene becomes quasi-free-standing and a local band gap appears at the Dirac point. The band gap changes with the substrate temperature during the formation of the graphene/Pb/Re(0001) system. The band gap is 0.3 eV at an annealing temperature of 620°C and it increases up to 0.4 eV upon annealing at 830°C. Based on our data, we conclude that the band gap is mainly caused by the hybridization of the graphene π state with the rhenium 5d states located near the Dirac point of the graphene π state.     

二维BC2 N薄片的结构稳定性和电子性质

采用基于密度泛函理论的第一性原理方法,对二维BC₂N薄片的结构稳定性和电子性质进行了系统的研究.计算了BC₂N化合物16种可能的二维单层结构.对它们的能带结构分析发现,对称性最高的构型与石墨烯一样是一种半金属,而其他二维结构则为有不同带隙的半导体,其中最稳定的构型是带隙值为1.63 eV的直接带隙半导体.对最稳定构型的差分电荷密度分析和Bader分析发现:在最稳定的构型中,C–C键、C–N键、C–B键和B–N键主要以共价键的形式呈现,也具有比较明显的离子性.在应力作用下最稳定构型的单层BC₂N的带隙宽度会发生变化,压缩时带隙变宽,而拉伸时带隙变窄,但仍然为直接带隙半导体. 关键词： 2N')" href="#">BC₂N 单层原子薄片 电子结构 从头计算     

Functionalizing AlN monolayer with hydroxyl group: Effect on the structural and electronic properties

Two-dimensional (2D) materials play key role in designing and fabricating diminutive optoelectronic devices with high efficiency. In this paper, we report the results of a comprehensive first-principles study on the structural and electronic properties of the pristine and hydroxyl group OH-functionalized (OH-AlN-OH) AlN monolayer. GGA-PBE and hybrid HSE06 functionals are employed to describe the exchange-correlation potential. According to our calculations, the pristine AlN monolayer has a wide indirect band gap of 2.954(4.000) eV determined by PBE(HSE06) level of theory. Indirect-direct gap transition is obtained through the chemical functionalization and the band gap reduces to 0.775(2.125) eV. Results shows that the OH-AlN-OH monolayer is more suitable for optoelectronic applications. Finally, the strain is proven to be efficient factor to tune the electronic properties of the studied monolayers.     

Band Gap Adjustment of SiC Honeycomb Structure through Hydrogenation and Fluorination

Previous calculations show that the two-dimensional(2 D) silicon carbide(SiC) honeycomb structure is a structurally stable monolayer. Following this, we investigate the electronic properties of the hydrogen and fluorine functionalized SiC monolayer by first-principles calculations. Our results show that the functionalized monolayer becomes metallic after semi-hydrogenation or semi-fluorination, while the semiconducting properties are obtained by the full functionalization. Compared with the bare SiC monolayer, the band gap of the fully hydrogenated system is increased, in comparison with the decrease of the gap in the fully fluorinated case. As a result, the band gap can be tuned from 0.73 to 4.14 eV by the functionalization. In addition to the metal-semiconductor transition, hydrogenation and functionalization also realize a direct-indirect semiconducting transition in the 2 D SiC monolayer. These results provide theoretical guidance for design of photoelectric devices based on the SiC monolayer.     

新型层状Bi2Se3的第一性原理研究

近年来,在石墨烯研究热潮的推动下,众多种类丰富、性能各异的二维化合物材料相继被发现,其中一些二维材料具有多种同素异构体,进而呈现出更丰富的性质.层状Bi2Se3由于其独特的物理性质,受到人们广泛的关注,而它的同素异构体尚未有人研究.本文采用基于密度泛函理论的结构搜索方法,预测了一个稳定的b-Bi2Se3新相,它具有良好的动力学和热力学稳定性,并在低Bi2Se3源化学势条件下容易形成.单层b-Bi2Se3是一个直接带隙为2.44 eV的二维半导体,其电子载流子有效质量低至0.52m0,在可见光范围内具有高达10^5 cm^–1的光吸收系数,并且能带边缘位置适中,可用于光催化水分解制氢气.此外,由于b-Bi2Se3在垂直层面方向的镜面对称性破缺,能够产生面外极化强度,具有0.58 pm/V的面外压电系数.鉴于其新颖的电子特性,二维b-Bi2Se3在未来的电子器件中可能发挥重要的作用.     

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。     

Structural,electronic and optical properties of Ca3Bi2: First-principles investigation

In this work by applying first principles calculations structural, electronic and optical properties of Ca₃Bi₂ compound in hexagonal and cubic phases are studied within the framework of the density functional theory using the full potential linearized augmented plane wave (FP-LAPW) approach. According to our study band gap for Ca₃Bi₂ in hexagonal phase are 0.47, 0.96 and 1?eV within the PBE-GGA, EV-GGA and mBJ-GGA, respectively. The corresponding values for cubic phase are 1.24, 2.08 and 2.14?eV, respectively. The effects of hydrostatic pressure on the behavior of the electronic properties such as band gap, valence bandwidths and anti-symmetry gap are investigated. It is found that the hydrostatic pressure increases the band widths of all bands below the Fermi energy while it decreases the band gap and the anti-symmetry gap. In our calculations, the dielectric tensor is derived within the random phase approximation (RPA). The first absorption peak in imaginary part of dielectric function for both phases is located in the energy range 2.0–2.5?eV which are beneficial to practical applications in optoelectronic devices in the visible spectral range. For instance, hexagonal phase of Ca₃Bi₂ with a band gap around 1?eV can be applied for photovoltaic application and cubic phase with a band gap of 2?eV can be used for water splitting application. Moreover, we found the optical spectra of hexagonal phase are anisotropic along E||x and E||z.     

Penta-SiC5 monolayer: A novel quasi-planar indirect semiconductor with a tunable wide band gap

In this paper, by using of the first principles calculations in the framework of the density functional theory, we systematically investigated the structure, stability, electronic and optical properties of a novel two-dimensional pentagonal monolayer semiconductors namely penta-SiC₅ monolayer. Comparing elemental silicon, diamond, and previously reported 2D carbon allotropes, our calculation shows that the predicted penta-SiC₅ monolayer has a metastable nature. The calculated results indicate that the predicted monolayer is an indirect semiconductor with a wide band gap of about 2.82 eV by using Heyd–Scuseria–Ernzerhof (HSE06) hybrid functional level of theory which can be effectively tuned by external biaxial strains. The obtained exceptional electronic properties suggest penta-SiC₅ monolayer as promising candidates for application in new electronic devices in nano scale.