CrO_2块体及其(001)和(100)表面的电子结构和磁性质

基于密度泛函理论的第一性原理计算,我们研究了CrO_2块体以及其(100)和(001)表面的磁性和电子结构.CrO_2(100)表面中表面层Cr原子向内收缩,而(001)表面中的表面层Cr原子却向外伸展;越往内层,原子驰豫幅度越小.由于表面效应.表面层原子的磁矩有了大幅的提升,其中(100)表面中表面层Cr原子的磁矩最高,为3.03μB.电子结构计算表明,CrO_2(100)和(001)表面均保持了块体中良好的半金属性,并且半金属带隙在(100)表面中受到了进一步的拓宽,因此具有更稳定的半金属性     

Heusler合金Co2CrGa(1 0 0)的表面结构、磁性和自旋极化

基于第一性原理计算,我们系统地呈现了三元合金Co2CrGa (100)表面的原子弛豫、磁性、电子结构以及表面原子极化行为。结果显示,由于Co-Ga和Co-Cr成键的差异,表面的Co和Cr原子分别向内层收缩和向外部真空层伸展。与块体相比较,表面Co和Cr原子的自旋磁矩由于局域性的提升而明显增大。在研究的Co2CrGa(100)不同原子端面中,可以观察到块体中的半金属带隙在CoCo和GaGa原子端面被大量的表面态所破坏,仅仅在CrGa和CrCr原子覆盖的端面,检测到100%的理想极化,预测其在隧道结中可能具有较佳的应用潜力。     

Cr含量对ZB型半金属铁磁体Cr_xZn_(1-x)Se磁电性能的影响

使用基于密度泛函理论的第一性原理方法,优化了闪锌矿结构的Cr_xZn_(1-x)Se(x=0.000,0.125,0.250和0.375)的2×2×2超胞的几何结构,计算了其自旋极化的态密度和能带结构、离子磁矩、电荷分布等磁电性能,详细分析了Cr含量对Cr_xZn_(1-x)Se磁电性能的影响.结果表明,Cr掺杂后ZB型ZnSe具有明显的半金属特性;当x=0.125,0.250和0.375时,Cr_xZn_(1-x)Se均有较宽的半金属带隙,从而可能具有较高的居里温度;当x=0.125时,Cr_xZn_(1-x)Se的半金属性最稳定;x=0.125,0.250和0.375时,Cr_xZn_(1-x)Se的超胞磁矩分别为整数磁矩4.0,8.0和12.0μ_B,而具有整数磁矩是半金属铁磁体非常重要的特征之一.Cr_xZn_(1-x)Se的半金属性和磁性主要来源于Cr离子的自旋极化,Cr离子的电子结构为Cr e_g~2↑e_g~1↓t_(2g)~3↑.     

第一性原理研究四元Heusler合金TiZrCoIn (100) 的表面结构、磁性及自旋极化率

本文利用第一性原理计算方法,对具有半金属性的四元Heusler合金TiZrCoIn两个不同终端表面效应进行了理论研究,主要针对表面效应对其结构、磁性、电子结构、自旋极化率及半金属性的影响来展开调研,以便寻求适合于隧道结的表面材料,为后续相关理论研究及实验提供一定参考。研究结果显示,两终端表面不同原子分别发生了不同程度的伸缩,同层原子发生错位,致使表面原子间距改变,进而改变它们之间的杂化作用,同时也影响着原子的磁矩。另外通过分析其态密度,发现TiCo-(100)和ZrIn-(100)两个终端表面由于受到表面效应的影响,其电子结构发生了很大的改变。块体TiZrCoIn原有的宽带隙和半金属性被表面态所破坏,但仍然保留着很高的自旋极化率,尤其是ZrIn-(100)终端表面,其费米面处呈现几乎100%的自旋极化率。     

过渡金属TM(V,Cr,Mn)掺杂ZnS的电子结构和磁性

采用基于密度泛函理论(DFT)的第一性原理赝势平面波方法,对过渡金属V、Cr、Mn 掺杂ZnS的超晶胞体系进行了几何结构优化,计算了晶格常数、电子结构与磁学性质。研究结果表明：掺入V,Cr后,ZnS表现出明显的半金属性,而掺入Mn后,半金属性不明显;掺入过渡金属TM(V,Cr,Mn)后系统产生的磁矩主要有杂质的3d态电子贡献,且磁矩的大小与过渡金属的电子排布有关。     

过渡金属TM(V,Cr,Mn)掺杂ZnS的电子结构和磁性

采用基于密度泛函理论(DFT)的第一性原理赝势平面波方法,对过渡金属V、Cr、Mn掺杂ZnS的超晶胞体系进行了几何结构优化,计算了晶格常数、电子结构与磁学性质.研究结果表明:掺入V,Cr后,ZnS表现出明显的半金属性,而掺入Mn后,半金属性不明显;掺入过渡金属TM(V,Cr,Mn)后系统产生的磁矩主要有杂质的3d态电子贡献,且磁矩的大小与过渡金属的电子排布有关.     

第一性原理研究semi-Heusler合金CoCrTe和CoCrSb的半金属性和磁性

采用第一性原理的全势能线性缀加平面波方法,对semi-Heusler合金CoCrTe和CoCrSb的电子结构进行自旋极化计算.CoCrTe和CoCrSb处于平衡晶格常数时是半金属性铁磁体,其半金属隙分别为0.28和0.22 eV,晶胞总磁矩为3.00μB和2.00μB.CoCrTe和CoCrSb的晶胞总磁矩主要来自于Cr原子磁矩.Co,Te和Sb的原子磁矩较小,它们的磁矩方向与Cr原子的磁矩方向相反.使晶格常数在±13%的范围内变化(相对于平衡晶格常数),并计算CoCrTe和CoCrSb的电子结构.计算研究表明,CoCrTe和CoCrSb的晶格常数变化分别在-11.4%—9.0%和-11.2%—2.0%时仍具有半金属性,并且它们晶胞总磁矩稳定于3.00μB和2.00μB.     

Heusler合金CO2CrGa(100)的表面结构、磁性和自旋极化

基于第一性原理计算,我们系统地呈现了三元合金Co2CrGa(100)表面的原子弛豫、磁性、电子结构以及表面原子极化行为.结果显示,由于Co-Ga和Co-Cr成键的差异,表面的Co和Cr原子分别向内层收缩和向外部真空层伸展.与块体相比较,表面Co和Cr原子的自旋磁矩由于局域性的提升而明显增大.在研究的Co2CrGa(100)不同原子端面中,可以观察到块体中的半金属带隙在CoCo和GaGa原子端面被大量的表面态所破坏,仅仅在CrGa和CrCr原子覆盖的端面,检测到100％的理想极化,预测其在隧道结中可能具有较佳的应用潜力.     

GaN(100)表面结构的第一性原理计算

用全势缀加平面波加局域轨道 (APW +lo)的方法计算了六方GaN及其非极性 ( 10 10 )表面的原子及电子结构 .计算出的六方GaN晶体结构参数 :晶格常数和体积弹性模量与实验值符合得很好 .用平板超原胞模型来计算GaN( 10 10 )表面的原子与电子结构 ,结果表明表面顶层原子发生键长收缩并扭转的弛豫特性 .表面阳离子向体内移动 ,趋向于sp2 平面构形 ;而表面阴离子向体外移动 ,趋向于锥形的p3构形 .弛豫后 ,表面实现由半金属性向半导体性的转变 .并且 ,表面电荷发生大的转移 ,参与表面键的重新杂化 ,使得表面原子的离子性减弱共价性增强 ,认为这就是表面原子键收缩并旋转的原因     

岩盐结构SrC(111)表面和(111)界面的d~0半金属性

利用第一性原理方法,本文研究了岩盐结构的SrC块材、(111)表面和(111)界面的电子结构和磁性.块材的SrC被证实是一个良好的d~0半金属铁磁体.计算结果显示(111)方向的C表面和Sr表面都保持了块材的半金属性.对于(111)方向四个可能的界面,态密度的计算显示C-Pb界面呈现半金属特性.本文对岩盐结构SrC块材、(111)表面和(111)界面半金属性的研究结果,将为高性能自旋电子器件的实际应用提供一定的理论指导.     

Surface and subsurface oxide formation on Ni(1 0 0) and Ni(1 1 1)

The oxidation of Ni(1 0 0) and Ni(1 1 1) at elevated temperatures and large oxygen exposures, typical of the methods used in the preparation of NiO(1 0 0) films for surface studies, has been investigated by medium energy ion scattering (MEIS) using 100 keV H⁺ incident ions. Oxide film growth proceeds significantly faster on Ni(1 1 1) than on Ni(1 0 0), but on both surfaces oxide penetration occurs to depths significantly greater than 100 Å with total exposures of 1200 and 6000 L respectively. The metal/oxide interface is extremely rough, with metallic Ni extending to the surface, even for much thicker oxide films on Ni(1 1 1). On Ni(1 1 1), NiO growth occurs with the (1 0 0) face parallel to the Ni(1 1 1) surface and the close-packed 〈1 1 0〉 directions parallel. On Ni(1 0 0) the MEIS blocking curves cannot be reconciled with a single orientation of NiO(1 0 0) (with the 〈1 1 0〉 directions parallel) on the surface, but is consistent with the substantial orientational disorder (including tilt) previously identified by spot-profile analysis LEED.     

Elastic waves at the (0 0 1) and (1 1 0) surfaces of AlN, GaN and InN

We have studied the acoustic waves in the (0 0 1) and (1 1 0) surfaces of AlN, GaN and InN. We have employed the surface Green function matching method and different sets of calculated elastic constants available in the literature for these materials, because no experimental values are available. Important differences are found for the velocities of the bulk and surface acoustic waves coming from these sets of elastic constants, in such a way that they could be easily measured by ultrasonic and Brillouin techniques. These results together with the expressions obtained here for the velocities of the acoustic waves in high symmetry directions could be used to determine the elastic coefficients of these materials.     

Growth of epitaxial thin Pd(1 1 1) films on Pt(1 1 1) and oxygen-terminated FeO(1 1 1) surfaces

Thin Pd films (1-10 monolayers, ML) were deposited at 35 K on a Pt(1 1 1) single crystal and on an oxygen-terminated FeO(1 1 1) monolayer supported on Pt(1 1 1). Low energy electron diffraction, Auger electron spectroscopy, and Kr and CO temperature programmed desorption techniques were used to investigate the annealing induced changes in the film surface morphology. For growth on Pt(1 1 1), the films order upon annealing to 500 K and form epitaxial Pd(1 1 1). Further annealing above 900 K results in Pd diffusion into the Pt(1 1 1) bulk and Pt-Pd alloy formation. Chemisorption of CO shows that even the first ordered monolayer of Pd on Pt(1 1 1) has adsorption properties identical to bulk Pd(1 1 1). Similar experiments conducted on FeO(1 1 1) indicate that 500 K annealing of a 10 ML thick Pd deposit also yields ordered Pd(1 1 1). In contrast, annealing of 1 and 3 ML thick Pd films did not result in formation of continuous Pd(1 1 1). We speculate that for these thinner films Pd diffuses underneath the FeO(1 1 1).     

Half-metallicity characteristic at zincblende CrSb(0 0 1) surfaces and its interfaces with GaSb(0 0 1) and InAs(0 0 1)

Electronic and magnetic properties of the zincblende CrSb(0 0 1) surfaces and its interfaces with GaSb(0 0 1) and InAs(0 0 1) semiconductors are studied within the framework of the density-functional theory using the FPLAPW+lo approach. We found that the Cr-terminated surfaces retain the half-metallic character, while the half-metallicity is destroyed for the Sb-terminated surfaces due to surface states, which originate from p electrons. The phase diagram obtained through the ab-initio atomistic thermodynamics shows that at phase transition has occurred. Also the half-metallicity character is preserved at both CrSb/GaSb and CrSb/InAs interfaces. The conduction band minimum (CBM) of CrSb in the minority spin case lies about 0.63 eV above that of InAs, suggesting that the majority spin can be injected into InAs without being flipped to the conduction bands of the minority spin. On the other hand the CrSb/GaSb interface has a greater valence band offset (VBO) compared with the CrSb/InAs interface and the minority electrons have lower contribution in the injected currents and hence more efficient spin injection into the GaSb semiconductor. Thus the CrSb/GaSb and CrSb/InAs heterojunctions can be useful in the field of spintronics.     

Water adsorption and dissociation on BeO(0 0 1) and (1 0 0) surfaces

Plateaus in water adsorption isotherms on hydroxylated BeO surfaces suggest significant differences between the hydroxylated (1 0 0) and (0 0 1) surface structures and reactivities. Density functional theory structures and energies clarify these differences. Using relaxed surface energies, a Wulff construction yields a prism crystal shape exposing long (1 0 0) sides and much smaller (0 0 1) faces. This is consistent with the BeO prisms observed when beryllium metal is oxidized. A water oxygen atom binds to a single surface beryllium ion in the preferred adsorption geometry on either surface. The water oxygen/beryllium bonding is stronger on the surface with greater beryllium atom exposure, namely the less-stable (0 0 1) surface. Water/beryllium coordination facilitates water dissociation. On the (0 0 1) surface, the dissociation products are a hydroxide bridging two beryllium ions and a metal-coordinated hydride with some surface charge depletion. On the (1 0 0) surface, water dissociates into a hydroxide ligating a Be atom and a proton coordinated to a surface oxygen but the lowest energy water state on the (1 0 0) surface is the undissociated metal-coordinated water. The (1 0 0) fully hydroxylated surface structure has a hydrogen bonding network which facilitates rapid proton shuffling within the network. The corresponding (0 0 1) hydroxylated surface is fairly open and lacks internal hydrogen bonding. This supports previous experimental interpretations of the step in water adsorption isotherms. Further, when the (1 0 0) surface is heated to 1000 K, hydroxides and protons associate and water desorbs. The more open (0 0 1) hydroxylated surface is stable at 1000 K. This is consistent with the experimental disappearance of the isotherm step when heating to 973 K.     

Density functional theory investigation of CN on Cu(1 1 1), Ni(1 1 1) and Ni(1 0 0)

The adsorption of CN on Cu(1 1 1), Ni(1 1 1) and Ni(1 0 0) has been investigated using density functional theory (DFT). While experimental studies of CN on Cu(1 1 1) show the molecular axis to be essentially parallel to the surface, the normally-preferred DFT approach using the generalised gradient approximation (GGA) yields a lowest energy configuration with the C-N axis perpendicular to the surface, although calculations using the local density approximation (LDA) do indicate that the experimental geometry is energetically favoured. The same conclusions are found for CN on Ni(1 1 1); on both surfaces bonding through the N atom is always unfavourable, in contrast to some earlier published results of ab initio calculations for Ni(1 1 1)/CN and Ni(1 0 0)/CN. The different predictions of the GGA and LDA approaches may lie in subtly different relative energies of the CN 5σ and 1π orbitals, a situation somewhat similar to that for CO adsorbed on Pt(1 1 1) which has proved challenging for DFT calculations. On Ni(1 0 0) GGA calculations favour a lying-down species in a hollow site in a geometry rather similar to that found experimentally and in GGA calculations for CN on Ni(1 1 0).     

Adsorption of water on TiN (1 0 0), (1 1 0) and (1 1 1) surfaces: A first-principles study

We use first-principles density functional theory-based calculations in the analysis of the interaction of H₂O with (1 0 0), (1 1 0) and (1 1 1) surfaces of TiN, and develop understanding in terms of surface energies, polarity of the surface and chemistry of the cation, through comparison with H₂O adsorption on ZrN. While water molecule physisorbs preferentially at Ti site of (1 0 0) and (1 1 1) surfaces, it adsorbs dissociatively on (1 1 0) surface of TiN with binding stronger than almost 1.32 eV/molecule. Our analysis reveals the following general trends: (a) surfaces with higher energies typically lead to stronger adsorption, (b) dissociative adsorption of H₂O necessarily occurs on a charge neutral high energy surface and (c) lower symmetry of the (1 1 0) plane results in many configurations of comparable stability, as opposed to the higher symmetry (1 0 0) and (1 1 1) surfaces, which also consistently explain the results of H₂O adsorption on MgO available in literature. Finally, weaker adsorption of H₂O on TiN than on ZrN can be rationalized in terms of greater chemical stability of Ti arising from its ability to be in mixed valence.     

Layer-resolved photoelectron diffraction from Si(0 0 1) and GaAs(0 0 1)

Photoelectron diffraction in the layer-resolved mode brings more detailed information about local atomic arrangement than is obtained in the standard mode. This is demonstrated in crystals with diamond and zinc-blende structures, both for unpolarized photon excitation as well as for circularly polarized excitation. The full angular distributions of photoemission intensities are evaluated for large atomic clusters representing ideally truncated surfaces of Si(0 0 1) and GaAs(0 0 1). Highly structured layer-resolved patterns enable a more detailed understanding of the standard mode outcomes. Photoelectron intensities from atomic layers placed at different depths under the crystal surface provide direct evidence about electron attenuation and its anisotropy in crystals.     

Comparing the band structure of Ag(1 1 1) monolayers on Ni(1 1 1) and Ni (0 0 1)

Ag(1 1 1) monolayers prepared on two substrates, Ni(1 1 1) and Ni(0 0 1), were studied with angle-resolved photoemission; their two-dimensional band dispersions were found to be identical within experimental uncertainties. Comparing the present results with those for Ag/Cu(0 0 1), the major difference is just a shift of 0.32 eV in all the binding energies. Thus the band topology of Ag overlayers in these systems is quite insensitive to the electronic and atomic structures of the substrates.