Spin current and its heat effect in a multichannel quantum wire with Rashba spin-orbit coupling

Using the perturbation method, we theoretically study the spin current and its heat effect in a multichannel quantum wire with Rashba spin-orbit coupling. The heat generated by the spin current is calculated. With the increase of the width of the quantum wire, the spin current and the heat generated both exhibit period oscillations with equal amplitudes. When the quantum-channel number is doubled, the oscillation periods of the spin current and of the heat generated both decrease by a factor of 2. For the spin current js,xy, the amplitude increases with the decrease of the quantum channel; while the amplitude of the spin current js,yx remains the same. Therefore we conclude that the effect of the quantum-channel number on the spin current js,xy is greater than that on the spin current js,yx. The strength of the Rashba spin-orbit coupling is tunable by the gate voltage, and the gate voltage can be varied experimentally, which implies a new method of detecting the. spin current. In addition, we can control the amplitude and the oscillation period of the spin current by controlling the number of the quantum channels. All these characteristics of the spin current will be very important for detecting and controlling the spin current, and especially for designing new spintronic devices in the future.

A pure spin-current injector of semiconductor quantum dots with Andreev reflection and Rashba spin-orbit coupling

We propose a four-terminal device consisting of two parallel quantum dots with Rashba spin-orbit interaction （RSOI）, coupled to two side superconductor leads and two common ferromagnetic leads, respectively. The two ferromagnetic leads and two quantum dots form a ring threaded by Aharonov-Bohm （AB） flux. This device possesses normal quasiparticle transmission between the two ferromagnetic leads, and normal and crossed Andreev reflections providing conductive holes. For the appropriate spin polarization of the ferromagnetic leads, RSOI and AB flux, the pure spin-up （or spin-down） current without net charge current in the right lead, which is due to the equal numbers of electrons and holes with the same spin-polarization moving along the same direction, can be obtained by adjusting the gate voltage, which may be used in practice as a pure spin-current injector.

Transport properties in a multi-terminal regular polygonal quantum ring with Rashba spin-orbit coupling

Transport properties in a multi-terminal regular polygonal quantum ring with Rashba spin-orbit coupling （SOC） are investigated analytically using quantum networks and the transport matrix metLod. The results show that conduc- tances remain at exactly the same values when the output leads are located at axisymmetric positions. However, for the nonaxisymmetrical case, there is a phase difference between the upper and lower arm, which leads to zero conductances appearing periodically. An isotropy of the conductance is destroyed by the Rashba SOC effect in the axisymmetric case. In addition, the position of zero conductance is regulated with the strength of the Rashba SOC.

Influence of spin-orbit coupling induced by in-plane external electric field on the intrinsic spin-Hall effect in a Rashba two-dimensional electron gas

We study theoretically the influence of spin-orbit coupling induced by in-plane external electric field on the intrinsic spin-Hall effect in a two-dimensional electron gas with Rashba spin-orbit coupling. We show that, after such an influence is taken into account, the static intrinsic spin-Hall effect can be stabilized in a disordered Rashba twodimensional electron gas, and the static intrinsic spin-Hall conductivity shall exhibit some interesting characteristics as conceived in some original theoretical proposals.

Influence of Rashba spin–orbit coupling on Josephson effect in triplet superconductor/two-dimensional semiconductor/triplet superconductor junctions

We study theoretically Josephson effect in a planar ballistic junction between two triplet superconductors with pwave orbital symmetries and separated by a two-dimensional(2D)semiconductor channel with strong Rashba spin–orbit coupling.In triplet superconductors,three types of orbital symmetries are considered.We use Bogoliubov–de Gennes formalism to describe quasiparticle propagations through the junction and the supercurrents are calculated in terms of Andreev reflection coefficients.The features of the variation of the supercurrents with the change of the strength of Rashba spin–orbit coupling are investigated in some detail.It is found that for the three types of orbital symmetries considered,both the magnitudes of supercurrent and the current-phase relations can be manipulated effectively by tuning the strength of Rashba spin–orbit coupling.The interplay of Rashba spin–orbit coupling and Zeeman magnetic field on supercurrent is also investigated in some detail.

Polarized spin transport in mesoscopic quantum rings with electron phonon and Rashba spin-orbit coupling

The influence of electron-phonon （EP） scattering on spin polarization of current output from a mesoscopic ring with Rashba spin-orbit （SO） interaction is numerically investigated. There are three leads connecting to the ring at different positionsl unpolarized current is injected to one of them, and the other two are output channels with different bias voltages. The spin polarization of current in the outgoing leads shows oscillations as a function of EP coupling strength owing to the quantum interference of EP states in the ring region. As temperature increases, the oscillations are evidently suppressed, implying decoherence of the EP states. The simulation shows that the magnitude of polarized current is sensitive to the location of the lead. The polarized current depends on the connecting position of the lead in a complicated way due to the spin-sensitive quantum interference effects caused by different phases accumulated by transmitting electrons with opposite spin states along different paths.

Interfacial spin Hall current in a Josephson junction with Rashba spin-orbit coupling

We theoretically investigate the spin transport properties of the Cooper pairs in a conventional Josephson junction with Rashba spin-orbit coupling considered in one of the superconducting leads.It is found that an angle-resolved spin supercurrent flows through the junction and a nonzero interfacial spin Hall current driven by the superconducting phase difference also appears at the interface.The physical origin of this is that the Rashba spin-orbit coupling can induce a triplet order parameter in the s-wave superconductor.The interfacial spin Hall current dependences on the system parameters are also discussed.

Coherent charge transport in ferromagnet/semiconductor nanowire/ferromagnet double barrier junctions with the interplay of Rashba spin-orbit coupling, induced superconducting pair potential,and external magnetic field

By solving the Bogoliubov-de Gennes equation, the influence of the interplay of Rashba spin-orbit coupling, induced superconducting pair potential, and external magnetic field on the spin-polarized coherent charge transport in ferromagnet/semiconductor nanowire/ferromagnet double barrier junctions is investigated based on the Blonder-Tinkham-Klapwijk theory. The coherence effect is characterized by the strong oscillations of the charge conductance as a function of the bias voltage or the thickness of the semiconductor nanowire, resulting from the quantum interference of incoming and outgoing quasiparticles in the nanowire. Such oscillations can be effectively modulated by varying the strength of the Rashba spin-orbit coupling, the thickness of the nanowire, or the strength of the external magnetic field. It is also shown that two different types of zero-bias conductance peaks may occur under some particular conditions, which have some different characteristics and may be due to different mechanisms.

Phase diagram and collective modes in Rashba spin–orbit coupled BEC: Effect of in-plane magnetic field

We studied the system of pure Rashba spin–orbit coupled Bose gas with an in-plane magnetic field. Based on the mean field theory, we obtained the zero temperature phase diagram of the system which exhibits three phases, plane wave（PW） phase, striped wave（SW） phase, and zero momentum（ZM） phase. It was shown that with a growing in-plane field,both SW and ZM phases will eventually turn into the PW phase. Furthermore, we adopted the Bogoliubov theory to study the excitation spectrum as well as the sound speed.

The effect of k-cubic Dresselhaus spin orbit coupling on the decay time of persistent spin helix states in semiconductor two-dimensional electron gases

We study the theoretical effect of k-cubic （i.e, cubic-in-momentum） Dresselhaus spin-orbit coupling on the decay time of persistent spin helix states in semiconductor two-dimensional electron gases. We show that the decay time of persistent spin helix states may be suppressed substantially by k-cubic Dresselhaus spin-orbit coupling, and after taking the effect of k-cubic Dresselhaus spin-orbit interaction into account, the theoretical results obtained accord both qualitatively and quantitatively with other recent experimental results.

Thermopower in parallel double quantum dots with Rashba spin-orbit interaction

Based on the Green＇s function technique and the equation of motion approach, this paper theoretically studies the thermoelectric effect in parallel coupled double quantum dots （DQDs）, in which Rashba spin-orbit interaction is taken into account. Rashba spin^rbit interaction contributions, even in a magnetic field, are exhibited obviously in the double quantum dots system for the thermoelectric effect. The periodic oscillation of thermopower can be controlled by tunning the Rashba spin^rbit interaction induced phase. The interesting spin-dependent thermoelectric effects will arise which has important influence on thermoelectric properties of the studied system.

Coexistence of giant Rashba spin splitting and quantum spin Hall effect in H–Pb–F

Rashba spin splitting(RSS)and quantum spin Hall effect(QSHE)have attracted enormous interest due to their great significance in the application of spintronics.In this work,we theoretically proposed a new two-dimensional(2D)material H–Pb–F with coexistence of giant RSS and quantum spin Hall effec by using the ab initio calculations.Our results show that H–Pb–F possesses giant RSS(1.21 eV·A)and the RSS can be tuned up to 4.16 e V·A by in-plane biaxial strain,which is a huge value among 2D materials.Furthermore,we also noticed that H–Pb–F is a 2D topological insulator(TI)duo to the strong spin–orbit coupling(SOC)interaction,and the large topological gap is up to 1.35 e V,which is large enough for for the observation of topological edge states at room temperature.The coexistence of giant RSS and quantum spin Hall effect greatly broadens the potential application of H–Pb–F in the field of spintronic devices.

H-Pb-Cl中可调控的巨型Rashba自旋劈裂和量子自旋霍尔效应

具有巨型Rashba自旋劈裂和量子自旋霍尔效应的材料在自旋电子器件应用中具有重要意义.基于第一性原理,提出一种可以将巨型Rashba自旋劈裂和量子自旋霍尔效应实现完美共存的二维(two dimension,2D)六角晶格材料H-Pb-Cl.由于系统空间反转对称性的破坏和本征电场的存在,H-Pb-Cl的电子能带中出现了巨型Rashba自旋劈裂现象(α_(R)=3.78 eV.A).此外,H-Pb-Cl的Rashba自旋劈裂是可以随双轴应力(-16%—16%)调控的.通过分析H-Pb-Cl的电子性质,发现在H-Pb-Cl费米面附近有一个巨大的带隙(1.31 eV),并且体系由于Pb原子的s-p轨道翻转使得拓扑不变量Z_(2)=1,这就表明H-Pb-Cl是一个具有巨大拓扑带隙的2D拓扑绝缘体.我们的研究为探索和实现Rashba自旋劈裂和量子自旋霍尔效应的共存提供了一种优良的潜在候选材料.

In_(0.53)Ga_(0.47)As/InP量子阱中的Rashba自旋-轨道耦合

利用k·p方法研究了In0.53Ga0.47As/InP窄禁带半导体量子阱结构中的Rashba自旋-轨道效应及其栅电压调控规律。随着栅电压Vg从-0.35V增加到0V,电子浓度ne从0.99×1011cm-2线性增大至9.20×1011cm-2,Rashba自旋-轨道耦合参数α从2.38×10-11eV·m减小到0.19×10-11eV·m,零场自旋分裂能Δ0高达4.63meV。结果表明通过栅电压可以有效调控样品中的自旋-轨道耦合强度,证明该结构是制备自旋场效应晶体管(SpinFET)的理想材料。

含Rashba-Dresselhaus双阶梯型量子线中电子的自旋电导开关效应

利用紧束缚近似的非平衡格林函数法,研究了含Rashba和Dresselhaus自旋轨道耦合效应的双阶梯型量子线中电子的自旋电导开关效应.结果表明在正向偏压下,系统有大的自旋电导出现;但在反向偏压下,这个大的自旋电导会消失.并且自旋电导随着Rashba和Dresselhaus自旋轨道耦合效应的变化呈现圆形结构,表明Rashba和Dresselhaus自旋轨道耦合效应引起自旋电导的作用是一样的,因此可以通过调节Rashba或Dresselhaus自旋轨道耦合效应来控制自旋电导.该系统在未来有可能用来制作全电自旋电导开关的量子线.

Proximity effects in normal mental/spin-splitting material/superconductor junctions

We extend the Blonder, Tinkham and Klapwijk （BTK） theory to the study of the coexistence between ferromagnetism and s-wave superconductivity in ferromagnet/superconductor （F/S） structures. It is found that the ferromagnetism and s-wave superconductivity can coexist near the F/S interface, which is induced by proximity effects. On the F side, the density of states （DOS） exhibits some superconducting-like properties, and it displays a damped oscillation from ‘0＇ to ‘v＇ states with increasing either the thickness of F film or the exchange energy. We also study the influences of the spin-polarized exchange splitting in the F and the spin-degeneracy by Rashba spin-orbit coupling （RSOC） in the two-dimensional electron gas （2DGE） on the proximity effects. It is shown that the case of Rashba spin-degeneracy is very different from that of the spin-polarized exchange splitting.

Photon-assisted electronic and spin transport through two T-shaped three-quantum-dot molecules embedded in an Aharonov-Bohm interferometer

We investigate the time-modulated electronic and spin transport properties through two T-shaped three-quantum-dot molecules embedded in an Aharonov-Bohm（A-B） interferometer. By using the Keldysh non-equilibrium Green＇s function technique, the photon-assisted spin-dependent average current is analyzed. The T-shaped three-quantum-dot molecule A-B interferometer exhibits excellent controllability in the average current resonance spectra by adjusting the interdot coupling strength, Rashba spin-orbit coupling strength, magnetic flux, and amplitude of the time-dependent external field.Efficient spin filtering and multiple electron-photon pump functions are exploited in the multi-quantum-dot molecule A-B interferometer by a time-modulated external field.

α-T_(3)晶格中量子反常霍尔效应研究

量子反常霍尔绝缘体具有与普通绝缘体一样的体带隙,但在其边缘或表面有拓扑保护的导电态。量子反常霍尔效应可以通过引入自旋轨道耦合相互作用和交换场来实现。文章重点研究了α-T_(3)晶格在两种Rashba自旋轨道耦合相互作用以及交换场的作用下,通过分析体系的相图、能带结构、边缘态和拓扑不变量,理论预测该体系为实现丰富的拓扑相提供了一个平台,包括半金属相和量子反常霍尔相。同时,该体系也是一个实现谷极化量子反常霍尔相的平台。在谷极化量子反常霍尔相中,边缘输运通道集中在单个能谷中,并且在边界上单向传播,可实现无耗散的100%的谷极化。我们的研究不仅发现了丰富的拓扑相,而且为拓扑电子学以及谷电子学应用提供了一个可行的平台。

Rashba效应影响下量子点中弱耦合束缚极化子的性质

采用改进的线性组合算符和幺正变换的方法研究了Rashba效应影响下量子点中弱耦合束缚极化子的性质,导出了Rashba效应影响下量子点中弱耦合束缚极化子的振动频率、有效质量、基态分裂能和相互作用能.数值计算结果表明随Rashba自旋-轨道耦合常数的增加,由于声子作用产生的附加能量对零磁场时自旋分裂能的影响占有绝对优势.库仑势对束缚极化子的基态能量的影响同时也占有绝对优势.所以,研究Rashba自旋轨道相互作用时声子的影响不可忽略.

Al_(0.6)Ga_(0.4)N/GaN/Al_(0.3)Ga_(0.7)N/Al_(0.6)Ga_(0.4)N量子阱中的Rashba自旋劈裂

正如人们所知,可以通过电场或者设计非对称的半导体异质结构来调控体系的结构反演不对称性(SIA)和Rashba自旋劈裂.本文研究了Al_(0.6)Ga_(0.4)N/GaN/Al_(0.3)Ga_(0.7)N/Al_(0.6)Ga_(0.4)N量子阱中第一子带的Rashba系数和Rashba自旋劈裂随Al_(0.3)Ga_(0.7)N插入层(右阱)的厚度w_s以及外加电场的变化关系,其中GaN层(左阱)的厚度为40-w_s?.发现随着w_s的增加,第一子带的Rashba系数和Rashba自旋劈裂首先增加,然后在w_s>20?时它们迅速减小,但是w_s>30?时Rashba自旋劈裂减小得更快,因为此时k_F也迅速减小.阱层对Rashba系数的贡献最大,界面的贡献次之且随w_s变化不是太明显,垒层的贡献相对比较小.然后,我们假设w_s=20?,发现外加电场可以很大程度上调制该体系的Rashba系数和Rashba自旋劈裂,当外加电场的方向同极化电场方向相同(相反)时,它们随着外加电场的增加而增加(减小).当外加电场从-1.5×10~8V·m^(-1)到1.5×10~8V·m^(-1)变化时,Rashba系数随着外加电场的改变而近似线性变化,Rashba自旋劈裂先增加得很快,然后近似线性增加,最后缓慢增加.研究结果表明可以通过改变GaN层和Al_(0.3)Ga_(0.7)N层的相对厚度以及外加电场来调节Al_(0.6)Ga_(0.4)N/GaN/Al_(0.3)Ga_(0.7)N/Al_(0.6)Ga_(0.4)N量子阱中的Rashba系数和Rashba自旋劈裂,这对于设计自旋电子学器件有些启示.