Electron-nucleus spin-correlation conservation of spin-dependent recombination in ${\mathrm{Ga}}^{2+}$ centers

Electron-nucleus spin-correlation conservation of spin-dependent recombination in ${Ga}^{2 +}$ centers

J. C. Sandoval-Santana, V. G. Ibarra-Sierra, H. Carrère, M. M. Afanasiev, L. A. Bakaleinikov, V. K. Kalevich, E. L. Ivchenko, X. Marie, T. Amand, A. Balocchi, and A. Kunold

Phys. Rev. B 101, 075201 – Published 6 February 2020

Abstract

Spin-dependent recombination in GaAsN offers many interesting possibilities in the design of spintronic devices mostly due to its astounding capability to reach conduction band electron spin polarization close to 100% at room temperature. The mechanism behind the spin selective capture of electrons in ${Ga}^{2 +}$ paramagnetic centers is revisited in this paper to address inconsistencies common to most previously presented models. Primarily, these errors manifest themselves as major disagreements with the experimental observations of two key characteristics of this phenomenon: the effective Overhauser-like magnetic field and the width of the photoluminescence Lorentzian-like curves as a function of the illumination power. These features are not only essential to understand the spin-dependent recombination in GaAsN, but are also key to the design of novel spintronic devices. Here we demonstrate that the particular structure of the electron capture expressions introduces spurious electron-nucleus correlations that artificially alter the balance between the hyperfine and the Zeeman contributions. This imbalance strongly distorts the effective magnetic field and width characteristics. In this work we propose an alternative recombination mechanism that preserves the electron-nucleus correlations and, at the same time, keeps the essential properties of the spin selective capture of electrons. This mechanism yields a significant improvement to the agreement between experimental and theoretical results. In particular, our model gives results in very good accord with the experimental effective Overhauser-like magnetic field and width data, and with the degree of circular polarization under oblique magnetic fields.

Received 22 November 2019
Accepted 21 January 2020

DOI:https://doi.org/10.1103/PhysRevB.101.075201

Physics Subject Headings (PhySH)

Spin dynamics Spin filtering Spin generation Spin relaxation Spintronics

III-V semiconductors Semiconductors

Condensed Matter, Materials & Applied Physics

Authors & Affiliations

J. C. Sandoval-Santana¹, V. G. Ibarra-Sierra ², H. Carrère³, M. M. Afanasiev⁴, L. A. Bakaleinikov ⁴, V. K. Kalevich ⁴, E. L. Ivchenko⁴, X. Marie³, T. Amand³, A. Balocchi³, and A. Kunold ^5,*

¹Instituto de Física, Universidad Nacional Autónoma de México, Apartado Postal 20-364 01000, Ciudad de México, Mexico
²Departamento de Sistemas Complejos, Instituto de Fisica, Universidad Nacional Autónoma de México, Apartado Postal 20-364 01000, Ciudad de México, Mexico
³Universitè de Toulouse, INSA-CNRS-UPS, LPCNO, 135 avenue de Rangueil, 31077 Toulouse, France
⁴Ioffe Physical-Technical Institute, 194021 St. Petersburg, Russia
⁵Área de Física Teórica y Materia Condensada, Universidad Autónoma Metropolitana Azcapotzalco, Av. San Pablo 180, Col. Reynosa-Tamaulipas, 02200 Cuidad de México, Mexico

^*akb@azc.uam.mx

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Vol. 101, Iss. 7 — 15 February 2020

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Figure 1
(a) Experimental behavior of the PL circular polarization degree $P_{e}$ as a function of the longitudinal magnetic field $B_{z}$ under right ( $σ^{+}$ ) and left ( $σ^{-}$ ) circularly polarized excitation light. (b) Effective magnetic field $B_{e}$ as a function of the illumination power. (c) Mean width $B_{1 / 2}$ as a function of the illumination power. The green open circles in panels (b) and (c) correspond to the experimental results and the solid blue lines are the theoretical calculations.
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Figure 2
(a) Number of singly and doubly occupied centers $N_{1}$ and $N_{2}$ as a function of time. (b) Electronic spin of singly and doubly occupied centers $S_{z}$ and $S_{c z}$ as a function of time. (c) Nuclear spin of singly and doubly occupied centers $I_{1 z}$ and $I_{2 z}$ as a function of time. (d) Hyperfine interaction as a function of time for singly and doubly occupied centers. The blue and orange solid lines correspond to singly and doubly occupied centers, respectively. The thick green line is the sum of singly and doubly occupied centers. The calculation was performed only taking into account the SDR dissipator of Eq. (43) for the following initial populations: $n_{- 1 / 2} = 0.22 N_{0}, n_{1 / 2} = 0.18 N_{0}, N_{- 1 / 2, - 1 / 2} = N_{- 1 / 2, 1 / 2} = N_{1 / 2, 3 / 2} = 0.2 N_{0}, N_{- 1 / 2, - 3 / 2} = 0.08 N_{0}, N_{- 1 / 2, 3 / 2} = 0.1 N_{0}, N_{1 / 2, - 3 / 2} = 0.02 N_{0}$ , and $N_{1 / 2, 1 / 2} = 0.1 N_{0}$ .
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Figure 3
(a) Number of singly and doubly occupied centers $N_{1}$ and $N_{2}$ as a function of time. (b) Electronic spin of singly and doubly occupied centers $S_{z}$ and $S_{c z}$ as a function of time. (c) Nuclear spin of singly and doubly occupied centers $I_{1 z}$ and $I_{2 z}$ as a function of time. (d) Hyperfine interaction as a function of time for singly and doubly occupied centers. The blue and orange solid lines correspond to singly and doubly occupied centers, respectively. The thick green line is the sum of singly and doubly occupied centers. The calculation was performed only taking into account the SDR dissipator of Eq. (55) for the following initial populations: $n_{- 1 / 2} = 0.22 N_{0}, n_{1 / 2} = 0.18 N_{0}, N_{- 1 / 2, - 1 / 2} = N_{- 1 / 2, 1 / 2} = N_{1 / 2, 3 / 2} = 0.2 N_{0}, N_{- 1 / 2, - 3 / 2} = 0.08 N_{0}, N_{- 1 / 2, 3 / 2} = 0.1 N_{0}, N_{1 / 2, - 3 / 2} = 0.02 N_{0}$ , and $N_{1 / 2, 1 / 2} = 0.1 N_{0}$ .
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Figure 4
(a) Experimental and (b) theoretical results for the degree of circular polarization as a function of the Faraday configuration magnetic field $B_{z}$ . In panel (a) the gray circles indicate the experimental points and the solid lines are a guide to the eye. Both panels show the curves corresponding to the DCP $P_{e}$ under right circularly polarized excitation ( $σ^{+}$ , blue solid lines) and left circularly polarized excitation ( $σ^{-}$ , green solid lines).
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Figure 5
(a) Effective magnetic field $B_{e}$ as a function of the illumination power. (b) Half width $B_{1 / 2}$ as a function of illumination power. (c) $ξ$ as a function of the illumination power. The solid orange and blue lines represent the theoretical calculations for right and left circularly polarized light, respectively. The green circles correspond to the experimental results.
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Figure 6
(a) Experimental and (b) theoretical results for degree of circular polarization as a function of an oblique magnetic field for diverse magnetic field orientations. The incidence light beam is perpendicular to the sample and the angles are measured with respect to this direction.
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Physical Review B

covering condensed matter and materials physics

Electron-nucleus spin-correlation conservation of spin-dependent recombination in ${Ga}^{2 +}$ centers

J. C. Sandoval-Santana, V. G. Ibarra-Sierra, H. Carrère, M. M. Afanasiev, L. A. Bakaleinikov, V. K. Kalevich, E. L. Ivchenko, X. Marie, T. Amand, A. Balocchi, and A. Kunold

Phys. Rev. B 101, 075201 – Published 6 February 2020

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Physical Review B

covering condensed matter and materials physics

Electron-nucleus spin-correlation conservation of spin-dependent recombination in Ga2+ centers

J. C. Sandoval-Santana, V. G. Ibarra-Sierra, H. Carrère, M. M. Afanasiev, L. A. Bakaleinikov, V. K. Kalevich, E. L. Ivchenko, X. Marie, T. Amand, A. Balocchi, and A. Kunold

Phys. Rev. B 101, 075201 – Published 6 February 2020

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Electron-nucleus spin-correlation conservation of spin-dependent recombination in ${Ga}^{2 +}$ centers