Spin-orbit coupling as a source of long-range triplet proximity effect in superconductor-ferromagnet hybrid structures

Bergeret, F. S.; Tokatly, I. V.

doi:10.1103/physrevb.89.134517

Cited by 192 publications

(264 citation statements)

References 80 publications

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“…For noncollinear magnetizations, e.g., due to domain walls [11][12][13][14][15][16][17], spin-active interfaces [18,19], multiple noncollinear magnetized ferromagnetic layers [17,20,21], helical magnets [22][23][24], or spin-orbit coupling [25], odd-frequency correlations with finite spin polarization can penetrate deeply into ferromagnets, as confirmed in several experiments [26][27][28][29][30][31][32].…”

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confidence: 81%

“…By a similar mechanism, Majorana fermions can also be generated in double quantum dots [7,8]. The idea of odd-frequency pairing has first been brought up by Berezinskii [9] as a possible explanation of superfluid 3 He but has experienced a revival in the context of superconductor-ferromagnet heterostructures [10].For noncollinear magnetizations, e.g., due to domain walls [11][12][13][14][15][16][17], spin-active interfaces [18,19], multiple noncollinear magnetized ferromagnetic layers [17,20,21], helical magnets [22][23][24], or spin-orbit coupling [25], odd-frequency correlations with finite spin polarization can penetrate deeply into ferromagnets, as confirmed in several experiments [26][27][28][29][30][31][32].Odd-frequency triplet pairing also appears in diffusive normal metals contacted by an even-frequency triplet superconductor [33].Finally, odd-frequency singlet superconductivity has only been theoretically predicted [34] without experimental confirmation so far. Quantum dots coupled to conventional superconductors show an interesting interplay of proximity effect and Coulomb interaction [35,36].…”

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confidence: 99%

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Unconventional superconductivity in double quantum dots

et al. 2014

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The formation of electron pairs is a prerequisite of superconductivity. The fermionic nature of electrons yields four classes of superconducting correlations with definite symmetry in spin, space and time. Here, we suggest double quantum dots coupled to conventional s-wave superconductors in the presence of inhomogeneous magnetic fields as a model system exhibiting unconventional pairing. Due to their small number of degrees of freedom, tunable by gate voltages, quantum-dot systems are ideal to gain fundamental insight in unconventional pairing. We propose two detection schemes for unconventional superconductivity, based on either Josephson or Andreev spectroscopy.PACS numbers: 73.23. Hk,74.45.+c,74.20.Rp,72.25.Mk Introduction.-Conventional superconductivity is well understood in terms of Bardeen-Cooper-Schrieffer (BCS) theory by the formation of spin-singlet Cooper pairs of electrons [1]. In certain unconventional superconductors, spin-triplet pairs are involved [2]. A further generalization is the notion of pairing of electrons at different times. There are four different classes of superconducting correlations with definite symmetries in spin, space (momentum), and time (frequency) under exchange of two electrons forming a Cooper pair. Even-frequency spin-singlet (odd in spin) Cooper pairs appear in conventional s-wave but also in high-T c d−wave [3] superconductors (even in space) while p-and f -wave pairing (odd in space) supports even-frequency spin triplets (even in spin). There is experimental evidence for triplet p-wave pairing (similar to superfluid 3 He [4]) in Sr 2 RuO 4 [2]. Recent proposals to induce triplet correlations in nanowires with strong spin-orbit interaction in proximity to s-wave superconductors were motivated by the prospect of creating Majorana fermions at the ends of the wire [5,6]. By a similar mechanism, Majorana fermions can also be generated in double quantum dots [7,8]. The idea of odd-frequency pairing has first been brought up by Berezinskii [9] as a possible explanation of superfluid 3 He but has experienced a revival in the context of superconductor-ferromagnet heterostructures [10].For noncollinear magnetizations, e.g., due to domain walls [11][12][13][14][15][16][17], spin-active interfaces [18,19], multiple noncollinear magnetized ferromagnetic layers [17,20,21], helical magnets [22][23][24], or spin-orbit coupling [25], odd-frequency correlations with finite spin polarization can penetrate deeply into ferromagnets, as confirmed in several experiments [26][27][28][29][30][31][32].Odd-frequency triplet pairing also appears in diffusive normal metals contacted by an even-frequency triplet superconductor [33].Finally, odd-frequency singlet superconductivity has only been theoretically predicted [34] without experimental confirmation so far. Quantum dots coupled to conventional superconductors show an interesting interplay of proximity effect and Coulomb interaction [35,36]. They have also been suggested as a tool to detect unconventional pairing [37]. In this Letter, we pr...

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confidence: 99%

Unconventional superconductivity in double quantum dots

et al. 2014

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“…(1) is the SU (2) approach, where the SOC is described in terms of a spin-dependent gauge field [43]. This formalism, introduced in the context of quarkgluon kinetic theory [53,54], was recently also extended to superconducting structures with SOC [55,56]. For a recent pedagogical introduction, see Ref.…”

Section: The Su(2) Approach For Intrinsic Socmentioning

confidence: 99%

Theory of current-induced spin polarization in an electron gas

et al. 2017

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We derive the Bloch equations for the spin dynamics of a two-dimensional electron gas in the presence of spin-orbit coupling. For the latter we consider both the intrinsic mechanisms of structure inversion asymmetry (Rashba) and bulk inversion asymmetry (Dresselhaus), and the extrinsic ones arising from the scattering from impurities. The derivation is based on the SU(2) gauge-field formulation of the Rashba-Dresselhaus spin-orbit coupling. Our main result is the identification of a spin-generation torque arising from Elliot-Yafet scattering, which opposes a similar term arising from Dyakonov-Perel relaxation. Such a torque, which to the best of our knowledge has gone unnoticed so far, is of basic nature, i. e. should be effective whenever Elliott-Yafet processes are present in a system with intrinsic spin-orbit coupling, irrespective of further specific details. The spin-generation torque contributes to the current-induced spin polarization (CISP), also known as inverse spin-galvanic or Edelstein effect. As a result, the behavior of the CISP turns out to be more complex than one would surmise from consideration of the internal Rashba-Dresselhaus fields alone. In particular, the symmetry of the current-induced spin polarization does not necessarily coincide with that of the internal Rashba-Dresselhaus field, and an out-of-plane component of the CISP is generally predicted, as observed in recent experiments. We also discuss the extension to the three-dimensional electron gas, which may be relevant for the interpretation of experiments in thin films.

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“…(1) in the z direction and use the BrataasNazarov-Bauer boundary condition at the NM/FMI interface [5]. From the solution one can obtain an expression for the nonlocal resistance at the FM detector that reads [37,42,43]…”

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Modulation of pure spin currents with a ferromagnetic insulator

et al. 2015

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We propose and demonstrate spin manipulation by magnetically controlled modulation of pure spin currents in cobalt/copper lateral spin valves, fabricated on top of the magnetic insulator Y 3 Fe 5 O 12 (YIG). The direction of the YIG magnetization can be controlled by a small magnetic field. We observe a clear modulation of the nonlocal resistance as a function of the orientation of the YIG magnetization with respect to the polarization of the spin current. Such a modulation can only be explained by assuming a finite spin-mixing conductance at the Cu/YIG interface, as it follows from the solution of the spin-diffusion equation Spintronics is a rapidly growing field that aims at using and manipulating not only the charge, but also the spin of the electron, which could lead to faster data processing, nonvolatility, and lower electrical power consumption as compared to conventional electronics [1]. Sophisticated applications such as hard-disk read heads and magnetic random access memory (MRAM) have been introduced in the last two decades.Further progress could be achieved with pure spin currents, which are an essential ingredient in an envisioned spin-only circuit that would integrate logics and memory [2]. The most basic unit in such a concept is the spin analog to the transistor, in which the manipulation of pure spin currents is crucial. The original proposal by Datta and Das [3], which is also applicable to pure spin currents [4], suggested a spin manipulation that would arise from the spin precession due to the spin-orbit interaction modulated by an electric field (Rashba coupling). However, a fundamental limitation appears here, because the best materials for spin transport are those showing the lowest spin-orbit interaction and, therefore, there has been no success in electrically manipulating the spins and propagating them at the same environment, with few exceptions [4].Alternative ways to control pure spin currents are thus desirable. One could take advantage of the spin-mixing conductance concept [5,6] at nonmagnetic metal (NM)/ferromagnetic insulator (FMI) interfaces, which governs the interaction between the spin currents present at the NM and the magnetization of the FMI. This concept is the basis of new spindependent phenomena, including spin pumping [6][7][8][9][10][11][12], spin Seebeck effect [6,13], and spin Hall magnetoresistance (SMR) [6,[14][15][16][17][18]. In these cases, a NM with large spin-orbit coupling is required to convert the involved spin currents into charge currents via the inverse spin Hall effect [19].In this Rapid Communication, we demonstrate an alternative way of modulating pure spin currents based on a magnetic, instead of electric, gating. To that end, we use lateral spin valves (LSVs). These devices allow an electrical injection and detection of pure spin currents in a NM channel by using * f.casanova@nanogune.eu ferromagnetic (FM) electrodes in a nonlocal configuration [20][21][22][23][24][25][26][27][28][29]. The LSVs have been fabricated on top of a FMI, in order to enab...

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Spin-orbit coupling as a source of long-range triplet proximity effect in superconductor-ferromagnet hybrid structures

Cited by 192 publications

References 80 publications

Unconventional superconductivity in double quantum dots

Unconventional superconductivity in double quantum dots

Theory of current-induced spin polarization in an electron gas

Modulation of pure spin currents with a ferromagnetic insulator

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