Bias dependence of spin injection into GaAs from Fe, FeCo, and (Ga,Mn)As contacts

Endres, Bernhard; Hoffmann, Frank; Wolf, Christian; Einwanger, Andreas; Utz, Martin; Schuh, Dieter; Woltersdorf, Georg; Ciorga, Mariusz; Weiss, Dieter; Back, Christian; Bayreuther, G.

doi:10.1063/1.3553932

Cited by 5 publications

(12 citation statements)

References 7 publications

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“…Finally, the sample is cleaved in the [110] direction along the transport channel, reducing the channel width to 40 μm. This exposes the (110) surface, which enables direct magneto-optical access to the spin accumulation underneath the injecting contacts [10][11][12][13]. We investigate samples from two different wafers, called sample A and sample B in the following.…”

Section: (A) (Red Layer)mentioning

confidence: 99%

Optical investigation of electrical spin injection into an inverted two-dimensional electron gas structure

et al. 2017

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We report on electrical spin injection from (Ga,Mn)As into a high-mobility two-dimensional electron gas confined at an (Al,Ga)As/GaAs interface. Besides standard nonlocal electrical detection, we use a magneto-optical approach which provides cross-sectional images of the spin accumulation at the cleaved edge of the sample, yielding spin decay lengths on the order of 2 μm. In some cases we find a nonmonotonic bias voltage dependence of the spin signal, which may be linked to ballistic tunneling effects during spin injection. We observe a clear Hanle depolarization using a technique which is free of dynamic nuclear polarization effects. Fitting the data with the standard drift-diffusion model of spin injection suggests averaged in-plane spin lifetimes on the order of 1 ns.

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Section: (A) (Red Layer)mentioning

confidence: 99%

Optical investigation of electrical spin injection into an inverted two-dimensional electron gas structure

et al. 2017

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“…This ensures that the quasi-static magnetization of the ferromagnetic contacts does not contribute to the Kerr signal171819. In addition, to eliminate any electro-optic Kerr rotation, the measurements are performed in remanence after saturating the magnetization along [1–10] and [−110], respectively.…”

Section: Methodsmentioning

confidence: 99%

“…In Sample A, both effects are demonstrated by using a laser beam simultaneously to generate electron-hole pairs and to detect spin accumulation via the polar magneto-optic Kerr effect. We employ a cross-sectional two-dimensional imaging method that allows probing the spin polarization also below the ferromagnetic contacts at cryogenic temperatures171819. For the optical detection, a modulation technique is used, so that the Kerr rotation θ K is strictly proportional to the spin accumulation in the n-GaAs channel at the laser spot position ( is the chemical potential for up/down spin electrons).…”

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Demonstration of the spin solar cell and spin photodiode effect

et al. 2013

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Spin injection and extraction are at the core of semiconductor spintronics. Electrical injection is one method of choice for the creation of a sizeable spin polarization in a semiconductor, requiring especially tailored tunnel or Schottky barriers. Alternatively, optical orientation can be used to generate spins in semiconductors with significant spin-orbit interaction, if optical selection rules are obeyed, typically by using circularly polarized light at a well-defined wavelength. Here we introduce a novel concept for spin injection/extraction that combines the principle of a solar cell with the creation of spin accumulation. We demonstrate that efficient optical spin injection can be achieved with unpolarized light by illuminating a p-n junction where the p-type region consists of a ferromagnet. The discovered mechanism opens the window for the optical generation of a sizeable spin accumulation also in semiconductors without direct band gap such as Si or Ge.

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“…This becomes obvious by comparing fitting results of Hanle data from a one-and a two-dimensional model. For our studies we employ a cross-sectional imaging method that allows to probe the two-dimensional spin polarization distribution even below the contacts 8,9 and compare the experimental results to two-dimensional drift-diffusion simulations.…”

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confidence: 99%

“…A square-wave bias voltage alternating between zero and V B is applied between the contacts and the Kerr rotation is detected synchronously with balanced photo-receivers and a lock-in technique. This ensures that the (quasistatic) magnetization of the ferromagnetic contacts does not contribute to the Kerr signal 8,9 . Fig.…”

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Nonuniform current and spin accumulation in a 1 μm thick n-GaAs channel

Endres

Ciorga

Wagner

et al. 2012

Applied Physics Letters

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The spin accumulation in an n-GaAs channel produced by spin extraction into a (Ga,Mn)As contact is measured by cross-sectional imaging of the spin polarization in GaAs. The spin polarization is observed in a 1 µm thick n-GaAs channel with the maximum polarization near the contact edge opposite to the maximum current density. The one-dimensional model of electron drift and spin diffusion frequently used cannot explain this observation. It also leads to incorrect spin lifetimes from Hanle curves with a strong bias and distance dependence. Numerical simulations based on a two-dimensional drift-diffusion model, however, reproduce the observed spin distribution quite well and lead to realistic spin lifetimes.

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Bias dependence of spin injection into GaAs from Fe, FeCo, and (Ga,Mn)As contacts

Cited by 5 publications

References 7 publications

Optical investigation of electrical spin injection into an inverted two-dimensional electron gas structure

Optical investigation of electrical spin injection into an inverted two-dimensional electron gas structure

Demonstration of the spin solar cell and spin photodiode effect

Nonuniform current and spin accumulation in a 1 μm thick n-GaAs channel

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