In layered semiconductors with spin-orbit interaction (SOI) a persistent spin helix (PSH) state with suppressed spin relaxation is expected if the strengths of the Rashba and Dresselhaus SOI terms, α and β, are equal. Here we demonstrate gate control and detection of the PSH in two-dimensional electron systems with strong SOI including terms cubic in momentum. We consider strain-free InGaAs/InAlAs quantum wells and first determine a ratio α/β 1 for nongated structures by measuring the spin-galvanic and circular photogalvanic effects. Upon gate tuning the Rashba SOI strength in a complementary magnetotransport experiment, we monitor the complete crossover from weak antilocalization via weak localization to weak antilocalization, where the emergence of weak localization reflects a PSH-type state. A corresponding numerical analysis reveals that such a PSH-type state indeed prevails even in presence of strong cubic SOI, however no longer at α = β. An electron moving in an electric field experiences, in its rest frame, an effective magnetic field pointing perpendicularly to its momentum. The coupling of the electron's spin to this magnetic field is known as spin-orbit interaction (SOI). The ability to control the corresponding magnetic field, and thereby spin states, all electrically in gated semiconductor heterostructures 1,2 is a major prerequisite and motivation for research towards future semiconductor spintronics. However, on the downside, the momentum changes of an electron moving through a semiconductor cause sudden changes in the magnetic field leading to spin randomization. Hence, suppression of spin relaxation in the presence of strong, tunable SOI is a major challenge of semiconductor spintronics.In III-V semiconductor heterostructures two different types of SOI exist: (i) Rashba SOI, 3 originating from structure inversion asymmetry (SIA), is linear in momentum k with a strength α that can be controlled by an electric gate.(ii) Dresselhaus SOI 4 is due to bulk inversion asymmetry (BIA), which gives rise to a band spin splitting, given by k-linear and k-cubic contributions. 5 The strength of the linear in k term β = γ k 2 z (where γ is a material parameter) can hardly be changed as it stems from crystal fields. These various spin-orbit terms in layered semiconductors are described by the Hamiltonian H SO = H R + H D with Rashba and Dresselhaus termswith σ x ,σ y the Pauli spin matrices. 7 If the k-cubic terms can be neglected, a special situation emerges if Rashba and Dresselhaus SOI are of equal strength: α = ±β.Then spin relaxation is suppressed. 8,9 A collinear alignment of Rashba and Dresselhaus effective magnetic fields gives rise to spin precession around a fixed axis, leading to spatially periodic modes referred to as persistent spin helix (PSH) and reflecting the underlying SU (2) symmetry in this case. 10The PSH is robust against all forms of spin-independent scattering. This favorable situation where spin relaxation is suppressed while the spin degree of freedom is still susceptible to electric...
We propose a method to determine the relative strength of Rashba and Dresselhaus spin-orbit interaction from transport measurements without the need of fitting parameters. To this end, we make use of the conductance anisotropy in narrow quantum wires with respect to the directions of an in-plane magnetic field, the quantum wire, and the crystal orientation. We support our proposal by numerical calculations of the conductance of quantum wires based on the Landauer formalism which show the applicability of the method to a wide range of parameters.
A geometric phase of electron spin is studied in arrays of InAlAs/InGaAs two-dimensional electron gas rings. By increasing the radius of the rings, the time-reversal symmetric Aharonov-Casher oscillations of the electrical resistance are shifted towards weaker spin-orbit interaction regions with their shortened period. We conclude that the shift is due to a modulation of the spin geometric phase, the maximum modulation of which is approximately 1.5 rad. We further show that the Aharonov-Casher oscillations in various radius arrays collapse onto a universal curve if the radius and the strength of Rashba spin-orbit interaction are taken into account. The result is interpreted as the observation of the effective spin-dependent flux through a ring.
The spin-orbit interaction plays a crucial role in diverse fields of condensed matter, including the investigation of Majorana fermions, topological insulators, quantum information and spintronics. In III-V zinc-blende semiconductor heterostructures, two types of spin-orbit interaction--Rashba and Dresselhaus--act on the electron spin as effective magnetic fields with different directions. They are characterized by coefficients α and β, respectively. When α is equal to β, the so-called persistent spin helix symmetry is realized. In this condition, invariance with respect to spin rotations is achieved even in the presence of the spin-orbit interaction, implying strongly enhanced spin lifetimes for spatially periodic spin modes. Existing methods to evaluate α/β require fitting analyses that often include ambiguity in the parameters used. Here, we experimentally demonstrate a simple and fitting parameter-free technique to determine α/β and to deduce the absolute values of α and β. The method is based on the detection of the effective magnetic field direction and the strength induced by the two spin-orbit interactions. Moreover, we observe the persistent spin helix symmetry by gate tuning.
We investigated the spin lifetime in gate-fitted InGaAs narrow wires from magnetotransport measurement. Applying positive gate bias voltage, the spin lifetimes in narrow wires became more than one order longer than those obtained from a Hall bar sample with two-dimensional electron gas. This enhancement of spin lifetime in gated wires is the first experimental evidence of dimensional confinement and resonant spin-orbit interaction effect controlled by gate bias voltage. Spin relaxation due to the cubic Dresselhaus term is negligible in the present InGaAs wires.
. In general, ESR requires two external magnetic fields: a static field (B 0 ) to split the spin states in energy and an oscillating field (B 1 ) with the frequency resonant to the splitting energy. However, spin manipulation methods relying on real magnetic fields-much broader than the size of individual electrons-are energetically inefficient and unsuitable for future device applications. Here we demonstrate an alternative approach where the spin-orbit interaction 7 of trajectory-controlled electrons induces effective B 0 and B 1 fields. These fields are created when electron spins surf on sound waves [8][9][10] along winding semiconductor channels. The resultant spin dynamics-mobile spin resonance-is equivalent to the usual ESR but requires neither static nor time-dependent real magnetic fields to manipulate electron spin coherence.In the electron systems in inhomogeneous magnetic fields or systems with spin-orbit coupling, the motion of electrons is converted to time-dependent effective magnetic fields. The latest studies have reported that ESR can be driven by effective B 1 fields, which are produced by the reciprocating motion of electrons with spatially dependent spin splitting [11][12][13] or with spin-orbit coupled systems [14][15][16] , but these techniques still need external B 0 fields. A promising approach for incorporating effective B 0 fields is the use of long-distance spin transport, which induces spin precessions around the static spin-orbit magnetic fields 9,17 . In addition, spin-qubit operations using moving quantum dots have been theoretically proposed 18 . Thus, we expect all of the magnetic fields needed for ESR to be replaced with spin-orbit effective magnetic fields (B SO ) by using trajectorycontrolled travelling electrons.Mobile spin resonance is based on the dependence of B SO on the electron momentum vector k. For simplicity, we assume a two-dimensional electron system in a (001) III-V quantum well with only k-linear terms in the Dresselhaus spin-orbit interaction 19 (SOI). The effective Dresselhaus field is described bywhere we used a coordinate system with base vectorsx Now we consider electrons travelling along the sinusoidal channel shown in Fig. 1b. At each position of the channel, the deflection angle of the path determines the direction of the k-vector. As a result, the moving electrons experience an effective magnetic field that swings with the frequency f = v y /λ, where v y is the time-averaged y-component of the electron velocity and λ is the period of the winding channel. In the reference frame moving with the electrons, the time-dependent effective magnetic field can be expressed as the sum of a static field (B To control the trajectory of travelling electrons, we adopted acoustically induced moving dots 21,22 produced in an undoped 20-nm-thick GaAs/AlGaAs (001) quantum well, where the SOI acting on the two-dimensionally confined electrons is dominated by the Dresselhaus term 10 . The piezoelectric field induced by a surface acoustic wave (SAW) beam propagating alongŷ (...
High-performance nanowire complementary metal-semiconductor inverters Appl. Phys. Lett. 93, 053105 (2008); 10.1063/1.2967725 Very low-voltage operation capability of complementary metal-oxide-semiconductor ring oscillators and logic gates J. Organic complementary-like inverters employing methanofullerene-based ambipolar field-effect transistors Appl. Phys. Lett. 85, 4205 (2004); 10.1063/1.1812577Off-state luminescence in metal-oxide-semiconductor field-effect transistors and its use as on-chip voltage probe
Most future information processing techniques using electron spins in non-magnetic semiconductors will require both the manipulation and transfer of spins without their coherence being lost. The spin–orbit effective magnetic field induced by drifting electrons enables us to rotate the electron spins in the absence of an external magnetic field. However, the fluctuations in the effective magnetic field originating from the random scattering of electrons also cause undesirable spin decoherence, which limits the length scale of the spin transport. Here we demonstrate the drift transport of electron spins adjusted to a robust spin structure, namely a persistent spin helix. We find that the persistent spin helix enhances the spatial coherence of drifting spins, resulting in maximized spin decay length near the persistent spin helix condition. Within the enhanced distance of the spin transport, the transport path of electron spins can be modulated by employing time-varying in-plane voltages.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.