功能化扶手椅型石墨烯纳米带异质结的磁器件特性

石墨烯在未来纳米电子器件领域具有广泛的应用前景, 但是基于扶手椅型石墨烯纳米带(AGNR)的磁输运性质的研究还比较少. 本文理论上提出AGNR边缘桥接过渡金属Mn原子, 再用双F 原子(或双H原子)饱和形成特殊化学修饰的纳米带(AGNR-Mn-F₂或AGNR-Mn-H₂), 并运用基于第一性原理和非平衡态格林函数相结合的方法对其磁输运性质进行理论计算. 结果表明: 这两种纳米带所构成的异质结(F₂-AGNR-Mn-H₂)具有优良的磁器件特性, 即在很宽的偏压范围内, 能实现100%的自旋极化, 且在P(在左右电极垂直加上相同方向的磁场)和AP构型(在左右电极垂直加上相反方向的磁场)时, 分别具有单自旋和双自旋过滤效应; 同时发现, 这种异质结也具有双自旋二极管效应, 它的最大整流比可达到10⁸. 此外, 改变开关磁场的方向, 即从一种磁构型变换为另一种磁构型时, 能产生明显的自旋阀效应, 其巨磁阻高达10⁸%. 这意味着这种特殊的异质结能同时实现优良的自旋过滤、双自旋二极管及巨磁阻效应, 这对于发展自旋磁器件有重要意义.     

Electronic structures for armchair-edge graphene nanoribbons under a small uniaxial strain

We theoretically investigate the electronic structures for armchair-edge graphene nanoribbons (AGNRs) under a small in-plane uniaxial strain along armchair (longitudinal) and zigzag (transversal) direction, respectively. We demonstrate that, by both the tight-binding calculation and first-principles study, the applying of a small asymmetrical strain results in variation of energy subband spacing, which opens a band gap for metallic AGNRs and modifies the band gaps for semiconducting AGNRs near the Fermi level. It is believed that these results are of importance in the band gap engineering and electromechanical applications of graphene-nanoribbon-based devices.     

Structural defects influence on the conductance of strained zigzag graphene nanoribbon

In this paper, we investigate the influence of point structural defects on the transport properties of zigzag graphene nanoribbons (ZGNRs) under uniaxial strain field, using the numerical studies based on the ab-initio calculation, the standard tight-binding model and Green's functions. The calculation results show that the direction of applied strain and defect type significantly affect the conductance properties of ZGNRs. The conductance of the defective nanoribbons generally decreases and some dips corresponding to complete electron backscattering is appeared. This behavior is originated from the different coupling between the conducting electronic states influenced by the wave function modification around the Fermi energy which depends on the defect type. We show that the presence of defects leads to a significant increase in local current. Furthermore, we have investigated the strain-tunable spin transport of defective ZGNRs in the presence of the exchange magnetic field and Rashba spin-orbit coupling (RSOC).     

Engineering the work function of armchair graphene nanoribbons using strain and functional species: a first principles study

First principles density functional theory calculations were performed to study the effects of strain, edge passivation, and surface functional species on the structural and electronic properties of armchair graphene nanoribbons (AGNRs), with a particular focus on the work function. The work function was found to increase with uniaxial tensile strain and decrease with compression. The variation of the work function under strain is primarily due to the shift of the Fermi energy with strain. In addition, the relationship between the work function variation and the core level shift with strain is discussed. Distinct trends of the core level shift under tensile and compressive strain were discovered. For AGNRs with the edge carbon atoms passivated by oxygen, the work function is higher than for nanoribbons with the edge passivated by hydrogen under a moderate strain. The difference between the work functions in these two edge passivations is enlarged (reduced) under a sufficient tensile (compressive) strain. This has been correlated to a direct-indirect bandgap transition for tensile strains of about 4% and to a structural transformation for large compressive strains at about - 12%. Furthermore, the effect of the surface species decoration, such as H, F, or OH with different covering density, was investigated. It was found that the work function varies with the type and coverage of surface functional species. Decoration with F and OH increases the work function while H decreases it. The surface functional species were decorated on either one side or both sides of AGNRs. The difference in the work functions between one-sided and two-sided decorations was found to be relatively small, which may suggest an introduced surface dipole plays a minor role.     

氮化硼纳米带功能化碳纳米管的热自旋输运性质

热自旋电子学器件结合了自旋电子学和热电子学各自的优点,对人类可持续发展具有重要作用.本文研究了锯齿形BN纳米带(ZBNRs)共价功能化碳纳米管(SWCNT)的电子结构,发现ZBNRs-B-(6,6)SWCNT为磁性半金属,nZBNRs-B-(6,6)SWCNT(n=2—8)为磁性金属;nZBNRs-N-(6,6)SWCNT(n=1—8)为双极化铁磁半导体;4ZBNRs-B-(4,4)SWCNT和4ZBNRs-N-(4,4)SWCNT为磁性半金属,4ZBNRs-B-(m,m)SWCNT(m=5—9)为磁性金属;4ZBNRs-N-(m,m)SWCNT(m=5—9)为双极化铁磁半导体.然后,基于锯齿形BN纳米带共价功能化碳纳米管设计了新型热自旋电子学器件,发现基于ZBNRs-N-(6,6)SWCNT的器件具有热自旋过滤效应;而8ZBNRs-N-(6,6)SWCNT和nZBNRs-B-(6,6)SWCNT(n=1,8)都存在自旋相关塞贝克效应.这些发现表明BN纳米带功能化碳纳米管在热自旋电子学器件方面具有潜在的应用.     

Reentrant spin glass behavior in antiferromagnetic single crystalline Ba6Mn24O48 nanoribbons

Single crystalline Ba₆Mn₂₄O₄₈ nanoribbons with diameters ranging from one hundred nanometers to a few hundred nanometers and length up to tens of microns are synthesized via a facile molten salt method. These nanoribbons are characterized by a range of methods including X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), energy dispersive X-ray spectroscopy (EDS), selected area electron diffraction (SAED) and high-resolution transmission electron microscopy (HRTEM). The magnetic properties of Ba₆Mn₂₄O₄₈ nanoribbons are investigated by the zero-field-cooled (ZFC), field-cooled (FC) magnetization, and ac susceptibility. Upon cooling, we find the reentrant spin glass (RSG) behavior in these nanoribbons, i.e., paramagnetic (PM), antiferromagnetic (AFM), and spin glass (SG). The RSG behavior might be due to the surface spin disorder, geometrical frustration and Mn³⁺/Mn⁴⁺ mixture in Ba₆Mn₂₄O₄₈ nanoribbons.     

铂掺杂扶手椅型石墨烯纳米带的电学特性研究

本文采用基于密度泛函理论(DFT)的第一性原理计算了铂原子填充扶手椅型石墨烯纳米带(AGNR)中双空位结构的电学性能.计算结果表明: 通过控制铂原子的掺杂位置, 可以实现纳米带循环经历小带隙半导体—金属—大带隙半导体的相变过程; 纳米带边缘位置是铂原子掺杂的最稳定位置, 边缘掺杂纳米带的带隙值随宽度的变化与本征AGNR一样可用三簇曲线表示, 但在较大宽度时简并成两条曲线, 一定程度上抑制了带隙值的振荡; 并且铂原子边缘掺杂导致宽度系数N_a = 3p和3p + 1(p是一个整数)的几个较窄纳米带的带隙中出现杂质能级, 有效地降低了其过大的带隙值. 此外, 铂掺杂AGNR的能带结构对掺杂浓度不是很敏感, 从而降低了对实验精度的挑战. 本文的计算有利于推动石墨烯纳米带在纳米电子学方面的应用.     

Rashba spin splitting in the Al0.3Ga0.7N/GaN heterostructure under uniaxial strain

By solving the Schrödinger and Poisson equations self-consistently, changes of the Rashba spin splitting for the Al_0.3Ga_0.7N/GaN heterostructure under uniaxial strain are calculated, and electrons are found to take up the first two subbands. The additional polarization induced by the uniaxial strain leads to a great enhancement of the built-in electric field and the 2DEG concentration. The Rashba spin splitting almost increases linearly with the uniaxial strain, and its amplitude increases by 36% with a strain of 4×10⁻³. The effect of electrons occupying more than one subband on the Rashba spin splitting is discussed. Results show the internal electric field caused by the polarization is crucial for the considerable Rashba spin splitting in the Al_0.3Ga_0.7N/GaN heterostructure and the magnitude of the Rashba spin splitting can be greatly modulated by the uniaxial strain, which would benefit further research and application of spintronics.     

Effect of electric field and magnetic field on spin transport in bilayer graphene armchair nanoribbons: A Monte Carlo simulation study

In this article we study the effect of external magnetic field and electric field on spin transport in bilayer armchair graphene nanoribbons (GNR) by employing semiclassical Monte Carlo approach. We include D'yakonov-Perel' (DP) relaxation due to structural inversion asymmetry (Rashba spin-orbit coupling) and Elliott-Yafet (EY) relaxation to model spin dephasing. In the model we neglect the effect of local magnetic moments due to adatoms and vacancies. We have considered injection polarization along z-direction perpendicular to the plane of graphene and the magnitude of ensemble averaged spin variation is studied along the x-direction which is the transport direction. To the best of our knowledge there has been no theoretical investigation of the effects of external magnetic field on spin transport in graphene nanoribbons. This theoretical investigation is important in order to identify the factors responsible for experimentally observed spin relaxation length in graphene GNRs.     

边界修饰醚基的锯齿形石墨烯纳米条带的场发射的第一性原理研究

采用一种基于密度泛函理论计算的自洽方法研究了边界修饰有C-O-C醚基的锯齿形石墨烯纳米条带(包括边界有连续的醚基ZGNR-CE和50%覆盖度的醚基ZGNR-AE)的电子场发射特性. 模拟结果显示两种纳米条带的场发射主要由布里渊区中心且靠近费米面的电子态所决定. 因为具有较低的功函数,ZGNR-CE条带能产生比未修饰的重构锯齿形石墨烯纳米条带强很多的场发射电流;而ZGNR-AE条带有着几乎完全自旋极化的场发射电流,尽管电流不够强. 另外在较低的外电场下,单轴方向的外加应变能有效调控它们的场发射电流,但ZGNR-AE条带的高自旋极化保持不变. 通过分析这些条带的功函数、能带结构以及结合边界电偶极模型,揭示了相关机制.     

Modulation of electronic properties with external fields in silicene-based nanostructures

This work reviews our recent works about the density functional theory(DFT) calculational aspects of electronic properties in silicene-based nanostructures with the modulation of external fields, such as electric field, strain, etc. For the two-dimensional(2D) silicene-based nonostructures, the magnetic moment of Fe-doped silicene shows a sharp jump at a threshold electric field, which indicates a good switching effect, implying potential applications as a magnetoelectric(ME) diode. With the electric field, the good controllability and sharp switching of the magnetism may offer a potential applications in the ME devices. For the one-dimensional(1D) nanostructures, the silicene nanoribbons with sawtooth edges(SSi NRs) are more stable than the zigzag silicene nanoribbons(ZSiNRs) and show spin-semiconducting features. Under external electric field or uniaxial compressive strain, the gapless spin-semiconductors are gained, which is significant in designing qubits for quantum computing in spintronics. The superlattice structures of silicene-based armchair nanoribbons(ASiSLs) is another example for 1D silicene nanostructures. The band structures of ASi SLs can be modulated by the size and strain of the superlattices. With the stain increased, the related energy gaps of ASi SLs will change, which are significantly different with that of the constituent nanoribbons. The results suggest potential applications in designing quantum wells.     

Reflection of spin waves from a ferromagnetic multilayer with interfacial coupling of finite strength (reflection of spin waves from multilayer)

The reflection coefficient of bulk spin waves from a ferromagnetic multilayer with periodically modulated parameters of the exchange interaction, the uniaxial magnetic anisotropy and the saturation magnetization (a magnonic crystal) is calculated. The dependence of the reflection coefficient upon the spin wave frequency and the values of the bias magnetic field, the parameter of interfacial coupling, and the internal structure of the unit cell are investigated.      

Spin-dependent transport properties of an armchair boron-phosphide nanoribbon embedded between two graphene nanoribbon electrodes

Using non-equilibrium Green׳s function and ab initio calculations we investigate structural, electronic, and transport properties of a junction consisting of armchair hexagonal boron phosphide nanoribbon (ABPNR) contacted by two semi-infinite electrodes composed of armchair graphene nanoribbons (AGNRs). We consider three different configurations including the pristine AGNR–BP–GNR and substitutions for Iron atoms, namely on phosphorus and boron atoms at one edge of the BP nanoribbon. The spin current polarization in all these cases is extracted for each structure and bias. Such hybrid system is found to exhibit not only significant spin-filter efficiency (SFE) but also tunable negative differential resistance (NDR).     

Current–voltage characteristics of armchair Sn nanoribbons

Two‐dimensional group‐IV lattices silicene and germanene are known to share many of graphene's remarkable mechanical and electronic properties. Due to the out‐of‐plane buckling of the former materials, there are more means of electronic funtionalization, e.g. by applying uniaxial strain or an out‐of‐plane electric field. We consider monolayer hexagonal Sn (stanene) as an ideal candidate to feasibly implement and exploit graphene physics for nanoelectronic applications: with increased out‐of‐plane buckling and sizable spin–orbit coupling it lends itself to improved Dirac cone engineering. We investigate the ballistic charge transport regime of armchair Sn nanoribbons, classified according to the ribbon width W = {3m – 1, 3m, 3m + 1} with integer m. We study transport through (non‐magnetic) armchair ribbons using a combination of density functional theory and non‐equilibrium Green's functions. Sn ribbons have earlier current onsets and carry currents 20% larger than C/Si/Ge‐nanoribbons as the contact resistance of these ribbons is found to be comparable. (© 2014 WILEY‐VCH Verlag GmbH &Co. KGaA, Weinheim)     

Half-metallicity induced by out-of-plane electric field on phosphorene nanoribbons

Exploring the half-metallic nanostructures with large band gap and high carrier mobility is a crucial solution for developing high-performance spintronic devices. The electric and magnetic properties of monolayer zigzag black-phosphorene nanoribbons (ZBPNRs) with various widths are analyzed by means of the first-principles calculations. Our results show that the magnetic ground state is dependent on the width of the nanoribbons. The ground state of narrow nanoribbons smaller than 8ZBPNRs prefers ferromagnetic order in the same edge but antiferromagnetic order between two opposite edges. In addition, we also calculate the electronic band dispersion, density of states and charge density difference of 8ZBPNRs under the action of out-of-plane electric field. More interesting, the addition of out-of-plane field can modulate antiferromagnetic semiconductor to the half metal by splitting the antiferromagnetic degeneracy. Our results propose a new approach to realize half-metal in phosphorene, which overcomes the drawbacks of graphene/silicene with negligible band gap as well as the transitional metal sulfide (TMS) with low carrier mobility.     

Phase transition in antiferromagnets with anisotropic exchange interactions and uniaxial anisotropy

Abstract

Following the Bogoliubov variational principle, the equilibrium and stability equations of the free energy for the two sublattice antiferromagnetic system with inter- and intrasublattice exchange interactions and with an external magnetic field are investigated. For the Ising spin system with uniaxial anisotropy, the phase diagrams have been calculated for various values of anisotropy constant d and the ratio of intra- to intersublattice interaction constants γ. It is shown that first-order, as well as second-order transitions, occur for γ > 0, whereas only a second-order transition occurs for γ ≦ 0, irrespective of the sign of d. Furthermore, similar calculations are extended for the anisotropic Heisenberg spin system and quite interesting phase diagrams have been obtained. Next, the effects of the anisotropic exchange interactions on the magnetic ordered states and the magnetizations of the singlet ground state system of spin one and with a uniaxial anisotropy term are investigated in the vicinity of the level crossing field H ? D/gμ _B . A field-induced ordered state without the transverse component of magnetization is shown to appear in a certain range of magnetic field as the spin dimensionality decreases. It has also turned out that the phase transition between this ordered state and the canted antiferromagnetic state ordinarily found for the isotropic singlet ground state system is of first order. Lastly, the stable spin configurations at a temperature of absolute zero for a two-sublattice uniaxial antiferromagnet under an external magnetic field of arbitrary direction are studied. In particular, the effects of a single ionic anisotropy D-term and anisotropy in the exchange interactions on the magnetic phases are investigated. The antiferromagnetic state has turned out to appear only for the external magnetic field along the easy axis of sublattice magnetization, and makes a first-order phase transition to the canted-spin state or the ferromagnetic state. For other field directions, no antiferromagnetic state appears and only a second-order phase transition between the canted-spin and the ferromagnetic states occurs. The critical field as a function of external field direction has been calculated for several D-values.     

FeN3掺杂扶手椅型石墨烯纳米条带的极强电流极化和微分负导效应

本文运用第一性原理研究了FeN₃掺杂扶手椅型和锯齿型石墨烯纳米条带的电子结构和输运性质. 结果表明,FeN₃掺杂可导致两种类型的条带的能带结构发生显著变化,导致体系具有稳定的室温铁磁基态. 但是,只有扶手椅型条带具有明显的负微分电导和极强的电流极化效应(接近100%). 这是由于FeN₃掺杂引入孤立的两条自旋向下能级,导致极强的电流极化. 同时,它们与自旋向下的不同子能带的耦合强度完全不同,导致体系呈现出负微分电导行为. 结果说明,通过FeN₃掺杂扶手椅型石墨烯纳米条带也可用于制备自旋电子学器件.     

Strain engineering of graphene nanoribbons: pseudomagnetic versus external magnetic fields

Bandgap opening due to strain engineering is a key architect for making graphene’s optoelectronic, straintronic, and spintronic devices. We study the bandgap opening due to strain induced ripple waves and investigate the interplay between pseudomagnetic fields and externally applied magnetic fields on the band structures and spin relaxation in graphene nanoribbons (GNRs). We show that electron-hole bands of GNRs are highly influenced (i.e. level crossing of the bands are possible) by coupling two combined effects: pseudomagnetic fields (PMF) originating from strain tensor and external magnetic fields. In particular, we show that the tuning of the spin-splitting band extends to large externally applied magnetic fields with increasing values of pseudomagnetic fields. Level crossings of the bands in strained GNRs can also be observed due to the interplay between pseudomagnetic fields and externally applied magnetic fields. We also investigate the influence of this interplay on the electromagnetic field mediated spin relaxation mechanism in GNRs. In particular, we show that the spin hot spot can be observed at approximately B = 65 T (the externally applied magnetic field) and B₀ = 53 T (the magnitude of induced pseudomagnetic field due to ripple waves) which may not be considered as an ideal location for the design of straintronic devices. Our analysis might be used for tuning the bandgaps in strained GNRs and utilized to design the optoelectronic devices for straintronic applications.     

Electronic transport for armchair graphene nanoribbons with a potential barrier

We theoretically investigate the electronic transport properties through a rectangular potential barrier embedded in armchair-edge graphene nanoribbons (AGNRs) of various widths. Using the Landauer formula and Dirac equation with the continuity conditions for all segments of wave functions at the interfaces between regions inside and outside the barrier, we calculate analytically the conductance and Fano factor for the both metallic and semiconducting AGNRs, respectively. It is shown that, by some numerical examples, at Dirac point the both types of AGNRs own a minimum conductance associated with the maximum Fano factor. The results are discussed and compared with the previous relevant works.     

单空位缺陷诱导的扶手椅型石墨烯纳米带电学性能的转变

本文基于密度泛函理论的第一性原理计算了单空位缺陷对 扶手椅型石墨烯纳米带电学特性的影响. 计算结果表明: 当单空位位于纳米带边缘位置时, 系统结构最稳定. 不同位置上单空位缺陷的引入都会使得原本为半导体的本征 扶手椅型石墨烯纳米带变成金属性; 随着单空位浓度的减小, 其对纳米带能带结构的影响逐渐减弱; 随着纳米带宽度的增大, 表征其金属性的特征值表现出震荡性的减弱. 单空位缺陷诱导的扶手椅型纳米带的半导体特性到金属特性的转变为石墨烯在 电子器件中的应用提供了理论指导. 关键词： 扶手椅型石墨烯纳米带 单空位缺陷 电学性能