Spin–orbit-induced hole spin relaxation in InAs and GaAs quantum dots

Climente, Juan I.; Segarra, Carlos; Planelles, Josep

doi:10.1088/1367-2630/15/9/093009

Cited by 20 publications

(37 citation statements)

References 54 publications

(192 reference statements)

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“…The period of the anisotropic leakage is critically dependent on the relative magnitude of Zeeman interaction terms linear and cubic in the magnetic field. The current and singlet-triplet exchange splitting can be effectively adjusted by an appropriate choice of field direction, providing a simple control variable for quantum information processing and a way of tailoring magnetic interactions in hole spin qubits.Spin-based quantum information processing platforms relying on hole quantum dots (QDs) have recently attracted considerable attention [1][2][3][4][5][6][7][8][9][10][11], since they permit long spin coherence and electrically driven spin resonance thanks to the strong hole spinorbit (SO) interaction [12][13][14][15][16][17][18][19][20]. Owing to their effective spin J = 3 2 , spin dynamics in hole systems often exhibits physics not found in electron systems [21][22][23][24][25][26].…”

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confidence: 99%

Spin blockade in hole quantum dots: Tuning exchange electrically and probing Zeeman interactions

et al. 2017

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Spin-orbit coupling is key to all-electrical control of quantum-dot spin qubits, and is frequently stronger for holes than for electrons. Here we investigate Pauli spin blockade for two heavy holes in a gated double quantum dot in an in-plane magnetic field. The interplay of the complex Zeeman and spin-orbit couplings causes a blockade leakage current anisotropic in the field direction. The period of the anisotropic leakage is critically dependent on the relative magnitude of Zeeman interaction terms linear and cubic in the magnetic field. The current and singlet-triplet exchange splitting can be effectively adjusted by an appropriate choice of field direction, providing a simple control variable for quantum information processing and a way of tailoring magnetic interactions in hole spin qubits.Spin-based quantum information processing platforms relying on hole quantum dots (QDs) have recently attracted considerable attention [1][2][3][4][5][6][7][8][9][10][11], since they permit long spin coherence and electrically driven spin resonance thanks to the strong hole spinorbit (SO) interaction [12][13][14][15][16][17][18][19][20]. Owing to their effective spin J = 3 2 , spin dynamics in hole systems often exhibits physics not found in electron systems [21][22][23][24][25][26]. Experimental progress in realizing high-quality two-dimensional (2D) and even lower-dimensional hole systems has opened the door to hole-based computing architectures [27][28][29][30]. Probing the strengths of SO coupling and hole-hole interactions is thus highly relevant for quantum computing. Pauli spin blockade [31,32], the blocking of charge transport through QDs due to the Pauli exclusion principle, may be employed to perform this task in InSb, Si, Ge-Si core-shell wires, and GaAs [7,8,11,33].Pauli spin blockade (PSB) is lifted by spin-flip processes most commonly originating in the SO or hyperfine interactions. Electron PSBs at low magnetic fields are primarily lifted by the hyperfine coupling to the nuclei [34][35][36], unless the singlet-triplet splitting is large due to a sizable interdot tunnel coupling [37][38][39]. Electron SO interaction only becomes a major lifting mechanism at stronger magnetic fields and strong interdot tunneling [38]. For hole QDs, in contrast, the strong SO interaction is expected to be the dominant blockade lifting mechanism [7,8,11,33] even at low magnetic fields, particularly due to the suppression of hole contact hyperfine interaction. Spin-flip cotunneling processes may also give rise to a leakage current [11].Here we investigate PSB in a gate-defined hole double QD in an in-plane magnetic field. We derive an effective SO tunneling Hamiltonian between (1, 1) and (0, 2), with (N L , N R ) charge state on the left and right dot. Our work shows that the PSB is anisotropic in the field orientation and strongly influenced by the complex Zeeman interaction, which in hole QDs may have terms both linear and cubic in the field strength. We find that the period of the anisotropic leakage is determined by the domin...

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Spin blockade in hole quantum dots: Tuning exchange electrically and probing Zeeman interactions

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“…The complete expressions and derivation of the piezoelectric potential and the deformation potential operators for the three phonon branches is presented in [31]. The transition rate between the initial hole state |Ψ h i and the final hole state |Ψ h f is estimated using the Fermi golden rule…”

Section: Theoretical Modelmentioning

confidence: 99%

“…[28] Several works have theoretically addressed the hole spin relaxation in single QDs taking into account different SOI mechanisms and have showed that one or another prevail depending on the QD traits. [20,29,30,31,32] By comparison, the spin relaxation of holes in DQDs is still poorly understood. This is inspite of their promising prospects for the development of quantum information architectures.…”

Section: Introductionmentioning

confidence: 99%

“…The hole states are simulated using three-dimensional (3D) Hamiltonians including not only quadratic-in-k LH-HH coupling present in the Luttinger-Kohn Hamiltonian, but also cubic Dresselhaus SOI, which was found to be potentially important in single InAs QDs. [31] Calculations are carried out for varying strength of an electric field applied along the DQD stacking direction. This makes possible to study the transition from atomic-like states confined in one of the constituent QDs to fully molecular-like states, which are obtained when the field brings the hole levels in the upper and lower dots into resonance.…”

Section: Introductionmentioning

confidence: 99%

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Hole spin relaxation in InAs/GaAs quantum dot molecules

Segarra

Climente

Rajadell

et al. 2015

J. Phys.: Condens. Matter

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Abstract. We calculate the spin-orbit induced hole spin relaxation between Zeeman sublevels of vertically stacked InAs quantum dots. The widely used Luttinger-Kohn Hamiltonian, which considers coupling of heavy-and light-holes, reveals that hole spin lifetimes (T 1 ) of molecular states significantly exceed those of single quantum dot states. However, this effect can be overcome when cubic Dresselhaus spin-orbit interaction is strong. Misalignment of the dots along the stacking direction is also found to be an important source of spin relaxation.

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“…12 and 15, which is confirmed here using exact numerical solutions of the three-dimensional system. [27][28][29] To understand the different magnitude of the gaps, note that D s 2 takes place at F $ 0, while D s 1 does so at F ( 0 (see the example in Fig. 1(b)).…”

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Large hole spin anticrossings in InAs/GaAs double quantum dots

Rajadell

Climente

Planelles

2013

Applied Physics Letters

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We show that hole states in InAs/GaAs double quantum dots can exhibit spin anticrossings of up to 1 meV, according to simulations with a three dimensional Burt-Foreman Hamiltonian including strain and piezoelectric fields. The spin mixing originates in the valence band spin-orbit interaction plus the spatial symmetry breaking arising from misalignment between the dots and piezoelectric potential. The values we report are in better agreement with experiments than previous theoretical estimates and yield good prospects for efficient hole spin control. V C 2013 AIP Publishing LLC.[http://dx.doi.org/10.1063/1.4823458]There is current interest in using the spin of carriers confined in semiconductor quantum dots (QDs) for single spintronic, optoelectronic, and quantum information research. 1-4 Self-assembled InAs/GaAs QDs have been particularly successful at this regard because they combine high optical activity, which enables precise optical preparation and read-out of the spin degrees of freedom, 5,6 with moderately strong spin-orbit interaction (SOI), which provides an additional knob for spin control.In general, the spin of electrons and holes in InAs QDs is a fairly good quantum number except in the vicinity of level crossings between states with orthogonal spins, 7 where SOI or hyperfine interaction with the lattice nuclei mixes the two states, lifting the degeneracy and forming a spin anticrossing. The importance of spin anticrossings, also referred to as spin hot spots, 3,8,9 lies in the fact that they lead to fast spin flips. For this reason they have been proposed and used for spin manipulation protocols (see, e.g., Refs. 10-12). A strong SOI is desirable to obtain large spin anticrossings, thereby enabling faster operations. In some protocols, large anticrossings are also convenient to enhance the fidelity of the operations. 12 For electrons, spin anticrossings are mainly due to Rashba and Dresselhaus SOI. Takahashi et al. reported gaps of 70-160 leV between the s and p -orbitals of single InAs/GaAs QDs. 13 Greilich et al. investigated spin anticrossings between s-shell singlet and triplet states of two electrons in vertically stacked double quantum dots (DQDs), obtaining gaps under 10 leV. 14 In the same work, it was observed that the corresponding gap for holes was 36 leV, four times greater. This is due to the inherent valence band SOI, which is generally stronger than that of the conduction band. Indeed, Doty et al. observed spin anticrossings as large as 200 leV for holes tunneling in the neutral exciton states of some self-assembled DQD structures. 15 Soon after, the same authors reported a gap of 400 leV on a similar system. 12 This is the largest spin anticrossing observed in the s-shell of InAs QDs so far.The origin of these large spin anticrossings was investigated by some of us in Ref. 15. It arises from a combination of valence band SOI plus strong spatial asymmetries. Separately, the QDs can be modeled as circular structures.The SOI then couples the Bloch and envelope angular momenta, giving ri...

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Spin–orbit-induced hole spin relaxation in InAs and GaAs quantum dots

Cited by 20 publications

References 54 publications

Spin blockade in hole quantum dots: Tuning exchange electrically and probing Zeeman interactions

Spin blockade in hole quantum dots: Tuning exchange electrically and probing Zeeman interactions

Hole spin relaxation in InAs/GaAs quantum dot molecules

Large hole spin anticrossings in InAs/GaAs double quantum dots

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