Toward high-frequency operation of spin lasers

Paulo E. Faria; Gaofeng Xu; Jeongsu Lee; Nils C. Gerhardt; Guilherme M. Sipahi; Igor Žutić

doi:10.1103/PhysRevB.92.075311

Toward high-frequency operation of spin lasers

Paulo E. Faria
, Gaofeng Xu
, Jeongsu Lee
, Nils C. Gerhardt
, Guilherme M. Sipahi
, Igor Žutić

Physics

SUNY Buffalo
Universidade de São Paulo
University of Regensburg
Ruhr University Bochum

Research output: Contribution to journal › Article › peer-review

63 Scopus citations

Abstract

Injecting spin-polarized carriers into semiconductor lasers provides important opportunities to extend what is known about spintronic devices, as well as to overcome many limitations of conventional (spin-unpolarized) lasers. By developing a microscopic model of spin-dependent optical gain derived from an accurate electronic structure in a quantum-well-based laser, we study how its operation properties can be modified by spin-polarized carriers, carrier density, and resonant cavity design. We reveal that by applying a uniaxial strain, it is possible to attain a large birefringence. While such birefringence is viewed as detrimental in conventional lasers, it could enable fast polarization oscillations of the emitted light in spin lasers, which can be exploited for optical communication and high-performance interconnects. The resulting oscillation frequency (>200 GHz) would significantly exceed the frequency range possible in conventional lasers.

Original language	English
Article number	075311
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	92
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevB.92.075311
State	Published - Aug 25 2015

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title = "Toward high-frequency operation of spin lasers",

abstract = "Injecting spin-polarized carriers into semiconductor lasers provides important opportunities to extend what is known about spintronic devices, as well as to overcome many limitations of conventional (spin-unpolarized) lasers. By developing a microscopic model of spin-dependent optical gain derived from an accurate electronic structure in a quantum-well-based laser, we study how its operation properties can be modified by spin-polarized carriers, carrier density, and resonant cavity design. We reveal that by applying a uniaxial strain, it is possible to attain a large birefringence. While such birefringence is viewed as detrimental in conventional lasers, it could enable fast polarization oscillations of the emitted light in spin lasers, which can be exploited for optical communication and high-performance interconnects. The resulting oscillation frequency (>200 GHz) would significantly exceed the frequency range possible in conventional lasers.",

author = "Faria, \{Paulo E.\} and Gaofeng Xu and Jeongsu Lee and Gerhardt, \{Nils C.\} and Sipahi, \{Guilherme M.\} and Igor {\v Z}uti{\'c}",

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AU - Faria, Paulo E.

AU - Xu, Gaofeng

AU - Lee, Jeongsu

AU - Gerhardt, Nils C.

AU - Sipahi, Guilherme M.

AU - Žutić, Igor

PY - 2015/8/25

Y1 - 2015/8/25

N2 - Injecting spin-polarized carriers into semiconductor lasers provides important opportunities to extend what is known about spintronic devices, as well as to overcome many limitations of conventional (spin-unpolarized) lasers. By developing a microscopic model of spin-dependent optical gain derived from an accurate electronic structure in a quantum-well-based laser, we study how its operation properties can be modified by spin-polarized carriers, carrier density, and resonant cavity design. We reveal that by applying a uniaxial strain, it is possible to attain a large birefringence. While such birefringence is viewed as detrimental in conventional lasers, it could enable fast polarization oscillations of the emitted light in spin lasers, which can be exploited for optical communication and high-performance interconnects. The resulting oscillation frequency (>200 GHz) would significantly exceed the frequency range possible in conventional lasers.

AB - Injecting spin-polarized carriers into semiconductor lasers provides important opportunities to extend what is known about spintronic devices, as well as to overcome many limitations of conventional (spin-unpolarized) lasers. By developing a microscopic model of spin-dependent optical gain derived from an accurate electronic structure in a quantum-well-based laser, we study how its operation properties can be modified by spin-polarized carriers, carrier density, and resonant cavity design. We reveal that by applying a uniaxial strain, it is possible to attain a large birefringence. While such birefringence is viewed as detrimental in conventional lasers, it could enable fast polarization oscillations of the emitted light in spin lasers, which can be exploited for optical communication and high-performance interconnects. The resulting oscillation frequency (>200 GHz) would significantly exceed the frequency range possible in conventional lasers.

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DO - 10.1103/PhysRevB.92.075311

M3 - Article

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JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 7

M1 - 075311

ER -

Toward high-frequency operation of spin lasers

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