On-demand generation of optically active defects in monolayer WS2by a focused helium ion beam

A. Micevic; N. Pettinger; A. Hötger; L. Sigl; M. Florian; T. Taniguchi; K. Watanabe; K. Müller; J. J. Finley; C. Kastl; A. W. Holleitner

doi:10.1063/5.0118697

On-demand generation of optically active defects in monolayer WS₂by a focused helium ion beam

A. Micevic, N. Pettinger, A. Hötger, L. Sigl, M. Florian, T. Taniguchi, K. Watanabe, K. Müller, J. J. Finley, C. Kastl, A. W. Holleitner

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12 Scopus citations

Abstract

We demonstrate that optically active emitters can be locally generated by focusing a He-ion beam onto monolayer WS2 encapsulated in hBN. The emitters show a low-temperature photoluminescence spectrum, which is well described by an independent Boson model for localized emitters. Consistently, the photoluminescence intensity of the emitters saturates at low excitation intensities, which is distinct to the photoluminescence of excitonic transitions in the investigated WS2 monolayers. The demonstrated method allows us to position defect emitters in WS2 monolayers on demand. A statistical analysis suggests the generation yield of individual emitters to be as high as 11% at the highest investigated He-ion doses.

Original language	English
Article number	183101
Journal	Applied Physics Letters
Volume	121
Issue number	18
DOIs	https://doi.org/10.1063/5.0118697
State	Published - 31 Oct 2022

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title = "On-demand generation of optically active defects in monolayer WS2by a focused helium ion beam",

abstract = "We demonstrate that optically active emitters can be locally generated by focusing a He-ion beam onto monolayer WS2 encapsulated in hBN. The emitters show a low-temperature photoluminescence spectrum, which is well described by an independent Boson model for localized emitters. Consistently, the photoluminescence intensity of the emitters saturates at low excitation intensities, which is distinct to the photoluminescence of excitonic transitions in the investigated WS2 monolayers. The demonstrated method allows us to position defect emitters in WS2 monolayers on demand. A statistical analysis suggests the generation yield of individual emitters to be as high as 11% at the highest investigated He-ion doses.",

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doi = "10.1063/5.0118697",

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TY - JOUR

T1 - On-demand generation of optically active defects in monolayer WS2by a focused helium ion beam

AU - Micevic, A.

AU - Pettinger, N.

AU - Hötger, A.

AU - Sigl, L.

AU - Florian, M.

AU - Taniguchi, T.

AU - Watanabe, K.

AU - Müller, K.

AU - Finley, J. J.

AU - Kastl, C.

AU - Holleitner, A. W.

PY - 2022/10/31

Y1 - 2022/10/31

N2 - We demonstrate that optically active emitters can be locally generated by focusing a He-ion beam onto monolayer WS2 encapsulated in hBN. The emitters show a low-temperature photoluminescence spectrum, which is well described by an independent Boson model for localized emitters. Consistently, the photoluminescence intensity of the emitters saturates at low excitation intensities, which is distinct to the photoluminescence of excitonic transitions in the investigated WS2 monolayers. The demonstrated method allows us to position defect emitters in WS2 monolayers on demand. A statistical analysis suggests the generation yield of individual emitters to be as high as 11% at the highest investigated He-ion doses.

AB - We demonstrate that optically active emitters can be locally generated by focusing a He-ion beam onto monolayer WS2 encapsulated in hBN. The emitters show a low-temperature photoluminescence spectrum, which is well described by an independent Boson model for localized emitters. Consistently, the photoluminescence intensity of the emitters saturates at low excitation intensities, which is distinct to the photoluminescence of excitonic transitions in the investigated WS2 monolayers. The demonstrated method allows us to position defect emitters in WS2 monolayers on demand. A statistical analysis suggests the generation yield of individual emitters to be as high as 11% at the highest investigated He-ion doses.

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U2 - 10.1063/5.0118697

DO - 10.1063/5.0118697

M3 - Article

AN - SCOPUS:85143254158

SN - 0003-6951

VL - 121

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 18

M1 - 183101

ER -

On-demand generation of optically active defects in monolayer WS₂by a focused helium ion beam

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