Spin relaxation dynamics of quasiclassical electrons in ballistic quantum dots with strong spin-orbit coupling

Chang, Cheng-Hung; Mal’shukov, A. G.; Chao, K. A.

doi:10.1103/physrevb.70.245309

Cited by 37 publications

(67 citation statements)

References 29 publications

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“…[5][6][7][8][9][10] This effect can be traced back to the specific form of the spin-orbit field in the Rashba Hamiltonian-being proportional to the velocity. 7 Here we formulate the argument for a system including Rashba and also linear Dresselhaus term within the spin-diffusion equation approach.…”

Section: ͑27͒mentioning

confidence: 99%

“…The maximum spin relaxation time occurs when the width is of the order of the bulk spin relaxation length. Remarkably, while the tendency to suppress spin relaxation in confined systems has been predicted in a number of theoretical works, [4][5][6][7][8][9][10] there has been no anticipation of the increase of the spin relaxation observed at the smallest widths. In this paper we show that spin active boundaries, not considered in the previous theoretical analysis, dramatically change the size dependence of the spin relaxation time in the small width limit and provide a useful point of view as far as the interpretation of the experiment is concerned.…”

Section: Introductionmentioning

confidence: 99%

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Spin relaxation in narrow wires of a two-dimensional electron gas

et al. 2006

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How does an initially homogeneous spin polarization in a confined two-dimensional electron gas with Rashba spin-orbit coupling evolve in time? How does the relaxation time depend on system size? We study these questions for systems of a size that is much larger than the Fermi wavelength, but comparable and even shorter than the spin relaxation length. Depending on the confinement spin relaxation may become faster or slower than in the bulk. An initially homogeneously polarized spin system evolves into a spiral pattern.

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Section: ͑27͒mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Spin relaxation in narrow wires of a two-dimensional electron gas

et al. 2006

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“…On the other hand, the presence of SO couplings makes the dynamics of transported spin in experimentally relevant confined structures strongly dependent on the properties of their interfaces, boundaries, and the attached electrodes, 53 even for semiclassical spatial propagation of charges which carry spins evolving according to quantum dynamical laws. 56 For example, heuristic arguments based on the Keldysh formalism applied to an infinite two-terminal structure (lacking actual lateral edges) of Ref. 27 suggest that nonequilibrium spin Hall accumulation S z m = 0 will appear only in the four corners at the lead/2DEG interfaces (due to J z y = 0 existing within a spin relaxation length L SO wide region around such interfaces), in contrast to the Keldysh formalism applied to finite-size 2DEG in the Landauer two-terminal setup where non-zero spin accumulation (with opposite sign on the two lateral edges 1,2 ) is found along the whole lateral edge.…”

Section: Bulk Vs Edge Local Spin Currents In Disordered Four-tementioning

confidence: 99%

Imaging mesoscopic spin Hall flow: Spatial distribution of local spin currents and spin densities in and out of multiterminal spin-orbit coupled semiconductor nanostructures

2006

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We introduce the concept of bond spin current, which describes the spin transport between two sites of the lattice model of a multiterminal spin-orbit (SO) coupled semiconductor nanostructure, and express it in terms of the spin-dependent nonequilibrium (Landauer-Keldysh) Green functions of the device. This formalism is applied to obtain the spatial distribution of microscopic spin currents in clean phase-coherent two-dimensional electron gas with the Rashba-type of SO coupling attached to four external leads. Together with the corresponding profiles of the stationary spin density, such visualization of the phase-coherent spin flow allow us to resolve several key issues for the understanding of mechanisms which generate pure spin Hall currents in the transverse leads of ballistic devices due to the flow of unpolarized charge current through their longitudinal leads: (i) while bond spin currents are non-zero locally within the SO coupled region even in equilibrium (when all leads are at the same potential), the total spin current obtained by summing the bond spin currents over an arbitrary cross section is zero so that no spin can actually be transported by such equilibrium currents; (ii) when device is brought into nonequilibrium steady current state by external voltage difference applied between the longitudinal leads, only the wave functions (or Green functions) around the Fermi energy contribute to the total spin current through a given transverse cross section; (iii) the total spin Hall current is not conserved within the SO coupled region; however, it becomes conserved and physically well-defined quantity in the ideal leads where it is, furthermore, equal to the spin current obtained within the multiprobe Landauer-Büttiker scattering formalism. The local spin current profiles crucially depend on whether the sample is smaller or greater than the spin precession length, thereby demonstrating its essential role as the characteristic mesoscale for the spin Hall effect in ballistic multiterminal semiconductor nanostructures. Although static spin-independent disorder reduces the magnitude of the total spin current in the leads, the bond spin currents continue to flow through the whole diffusive 2DEG sample, without being localized as edge spin currents around any of its boundaries. Recent experimental observation of the spin Hall effect 1,2 opens new avenues for the understanding of fundamental role which spin-orbit (SO) couplings 3,4 can play in transport and equilibrium properties of semiconductor structures. While SO coupling effects are tiny relativistic corrections for particles moving through electric fields in vacuum, they can be enhanced in solids by several orders of magnitude due to the interplay of crystal symmetry and strong crystalline potential. 3,4 Furthermore, harnessing of spin currents induced by the spin Hall effect offers new possibilities for the envisioned all-electrical manipulation of spin for semiconductor spintronics applications 5 where electrical fields can access individual spins on s...

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“…46 Related trace formulas appear also in trajectory-based treatments of electronic systems with spin-orbit interaction. [47][48][49][50] We note that semiclassical methods have also been used to study graphene in magnetic fields. [51][52][53] Following the concepts outlined above we address edge effects on the electronic spectra of closed graphene cavities and quantum transport through open graphene systems in two consecutive papers.…”

Section: B Scope Of This Workmentioning

confidence: 99%

Edge effects in graphene nanostructures: From multiple reflection expansion to density of states

2011

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We study the influence of different edge types on the electronic density of states of graphene nanostructures. To this end we develop an exact expansion for the single-particle Green's function of ballistic graphene structures in terms of multiple reflections from the system boundary, which allows for a natural treatment of edge effects. We first apply this formalism to calculate the average density of states of graphene billiards. While the leading term in the corresponding Weyl expansion is proportional to the billiard area, we find that the contribution that usually scales with the total length of the system boundary differs significantly from what one finds in semiconductor-based, Schrödinger-type billiards: The latter term vanishes for armchair and infinite-mass edges and is proportional to the zigzag edge length, highlighting the prominent role of zigzag edges in graphene. We then compute analytical expressions for the density of states oscillations and energy levels within a trajectory-based semiclassical approach. We derive a Dirac version of Gutzwiller's trace formula for classically chaotic graphene billiards and further obtain semiclassical trace formulas for the density of states oscillations in regular graphene cavities. We find that edge-dependent interference of pseudospins in graphene crucially affects the quantum spectrum.

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Spin relaxation dynamics of quasiclassical electrons in ballistic quantum dots with strong spin-orbit coupling

Cited by 37 publications

References 29 publications

Spin relaxation in narrow wires of a two-dimensional electron gas

Spin relaxation in narrow wires of a two-dimensional electron gas

Imaging mesoscopic spin Hall flow: Spatial distribution of local spin currents and spin densities in and out of multiterminal spin-orbit coupled semiconductor nanostructures

Edge effects in graphene nanostructures: From multiple reflection expansion to density of states

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