On-chip spin-orbit locking of quantum emitters in 2D materials for chiral emission

Yichen Ma; Haoqi Zhao; Na Liu; Zihe Gao; Seyed Sepehr Mohajerani; Licheng Xiao; James Hone; Liang Feng; Stefan Strauf

doi:10.1364/OPTICA.463481

On-chip spin-orbit locking of quantum emitters in 2D materials for chiral emission

Yichen Ma, Haoqi Zhao, Na Liu, Zihe Gao, Seyed Sepehr Mohajerani, Licheng Xiao, James Hone, Liang Feng, Stefan Strauf

Department of Physics

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

21 Scopus citations

Abstract

Light carries both spin angular momentum (SAM) and orbital angular momentum (OAM), which can be used as potential degrees of freedom for quantum information processing. Quantum emitters are ideal candidates towards on-chip control and manipulation of the full SAM–OAM state space. Here, we show coupling of a spin-polarized quantum emitter in a monolayer WSe₂ with the whispering gallery mode of a Si₃N₄ ring resonator. The cavity mode carries a transverse SAM of σ = ±1 in the evanescent regions, with the sign depending on the orbital power flow direction of the light. By tailoring the cavity–emitter interaction, we couple the intrinsic spin state of the quantum emitter to the SAM and propagation direction of the cavity mode, which leads to spin–orbit locking and subsequent chiral single-photon emission. Furthermore, by engineering how light is scattered from the WGM, we create a high-order Bessel beam which opens up the possibility to generate optical vortex carrying OAM states.

Original language	English
Pages (from-to)	953-958
Number of pages	6
Journal	Optica
Volume	9
Issue number	8
DOIs	https://doi.org/10.1364/OPTICA.463481
State	Published - Aug 2022

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title = "On-chip spin-orbit locking of quantum emitters in 2D materials for chiral emission",

abstract = "Light carries both spin angular momentum (SAM) and orbital angular momentum (OAM), which can be used as potential degrees of freedom for quantum information processing. Quantum emitters are ideal candidates towards on-chip control and manipulation of the full SAM–OAM state space. Here, we show coupling of a spin-polarized quantum emitter in a monolayer WSe2 with the whispering gallery mode of a Si3N4 ring resonator. The cavity mode carries a transverse SAM of σ = ±1 in the evanescent regions, with the sign depending on the orbital power flow direction of the light. By tailoring the cavity–emitter interaction, we couple the intrinsic spin state of the quantum emitter to the SAM and propagation direction of the cavity mode, which leads to spin–orbit locking and subsequent chiral single-photon emission. Furthermore, by engineering how light is scattered from the WGM, we create a high-order Bessel beam which opens up the possibility to generate optical vortex carrying OAM states.",

author = "Yichen Ma and Haoqi Zhao and Na Liu and Zihe Gao and Mohajerani, {Seyed Sepehr} and Licheng Xiao and James Hone and Liang Feng and Stefan Strauf",

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T1 - On-chip spin-orbit locking of quantum emitters in 2D materials for chiral emission

AU - Ma, Yichen

AU - Zhao, Haoqi

AU - Liu, Na

AU - Gao, Zihe

AU - Mohajerani, Seyed Sepehr

AU - Xiao, Licheng

AU - Hone, James

AU - Feng, Liang

AU - Strauf, Stefan

PY - 2022/8

Y1 - 2022/8

N2 - Light carries both spin angular momentum (SAM) and orbital angular momentum (OAM), which can be used as potential degrees of freedom for quantum information processing. Quantum emitters are ideal candidates towards on-chip control and manipulation of the full SAM–OAM state space. Here, we show coupling of a spin-polarized quantum emitter in a monolayer WSe2 with the whispering gallery mode of a Si3N4 ring resonator. The cavity mode carries a transverse SAM of σ = ±1 in the evanescent regions, with the sign depending on the orbital power flow direction of the light. By tailoring the cavity–emitter interaction, we couple the intrinsic spin state of the quantum emitter to the SAM and propagation direction of the cavity mode, which leads to spin–orbit locking and subsequent chiral single-photon emission. Furthermore, by engineering how light is scattered from the WGM, we create a high-order Bessel beam which opens up the possibility to generate optical vortex carrying OAM states.

AB - Light carries both spin angular momentum (SAM) and orbital angular momentum (OAM), which can be used as potential degrees of freedom for quantum information processing. Quantum emitters are ideal candidates towards on-chip control and manipulation of the full SAM–OAM state space. Here, we show coupling of a spin-polarized quantum emitter in a monolayer WSe2 with the whispering gallery mode of a Si3N4 ring resonator. The cavity mode carries a transverse SAM of σ = ±1 in the evanescent regions, with the sign depending on the orbital power flow direction of the light. By tailoring the cavity–emitter interaction, we couple the intrinsic spin state of the quantum emitter to the SAM and propagation direction of the cavity mode, which leads to spin–orbit locking and subsequent chiral single-photon emission. Furthermore, by engineering how light is scattered from the WGM, we create a high-order Bessel beam which opens up the possibility to generate optical vortex carrying OAM states.

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JO - Optica

JF - Optica

IS - 8

ER -

On-chip spin-orbit locking of quantum emitters in 2D materials for chiral emission

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