Engineering the Luminescence and Generation of Individual Defect Emitters in Atomically Thin MoS<sub>2</sub>

Klein, Julian; Sigl, Lukas; Gyger, Samuel; Barthelmi, Katja; Florian, Matthias; Rey, S.; Taniguchi, Takashi; Watanabe, Kenji; Jahnke, F.; Kastl, Christoph; Zwiller, Val; Jöns, Klaus D.; Müller, Kai; Wurstbauer, Ursula; Finley, Jonathan J.; Holleitner, Alexander W.

doi:10.1021/acsphotonics.0c01907

Cited by 61 publications

(94 citation statements)

References 49 publications

(103 reference statements)

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“…All of them gave rise to small ensembles of similar emission wavelength. The ensemble distribution, inferred from the PL spectra of all 26 spots, has a full width at half maximum (FWHM) of 3 meV (see Supplementary note 3 ), which is an order of magnitude narrower than the state of the art in 2D materials 23 . We estimate the number of emitters per site to be of order of a few tens, as confirmed by photon correlation measurements (see Supplementary note 4 ).…”

Section: Resultsmentioning

confidence: 98%

“…Moreover, the latter method results in limited possibilities of subsequent integration. In the 2D material MoS 2 , deterministic positioning with high precision ( ~ 10 nm) has been achieved 22 , 23 using He ion beam, but at the current stage the generated SPEs suffer from low count rates and large linewidths, which constitutes a major drawback for applications to photonic quantum information.…”

Section: Introductionmentioning

confidence: 99%

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Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

et al. 2021

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Single photon emitters (SPEs) in low-dimensional layered materials have recently gained a large interest owing to the auspicious perspectives of integration and extreme miniaturization offered by this class of materials. However, accurate control of both the spatial location and the emission wavelength of the quantum emitters is essentially lacking to date, thus hindering further technological steps towards scalable quantum photonic devices. Here, we evidence SPEs in high purity synthetic hexagonal boron nitride (hBN) that can be activated by an electron beam at chosen locations. SPE ensembles are generated with a spatial accuracy better than the cubed emission wavelength, thus opening the way to integration in optical microstructures. Stable and bright single photon emission is subsequently observed in the visible range up to room temperature upon non-resonant laser excitation. Moreover, the low-temperature emission wavelength is reproducible, with an ensemble distribution of width 3 meV, a statistical dispersion that is more than one order of magnitude lower than the narrowest wavelength spreads obtained in epitaxial hBN samples. Our findings constitute an essential step towards the realization of top-down integrated devices based on identical quantum emitters in 2D materials.

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Section: Resultsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

et al. 2021

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“…The small exciton redshift in the He-ion treated sample can likely be attributed to the increased dielectric screening in the fully encapsulated samples 28 . Additionally, inhomogeneous broadening effects due to a locally varying dielectric environment near the defects may result in an uncertainty of the defect emission line on the order of several meV 29,30 . The improved inhomogeneous broadening agrees with previous studies of fully hBN encapsulated heterostructures 26 .…”

Section: Resultsmentioning

confidence: 99%

“…To independently corroborate the value of the thermal activation energy and to quantify the absolute number of defects generated at a given temperature, we conducted a Raman study of additional, thermally annealed samples (Supplementary Note 4). At large enough defect densities, the inter-defect distance, or equivalently the absolute value of the defect density, can be inferred from a shift of the characteristic Raman modes due to phonon confinement effects 30,37,38 . From these experiments we extract an activation energy of (0.48 ± 0.23) eV for thermal defect generation, which agrees well with our in-situ study within the experimental uncertainty.…”

Section: Resultsmentioning

confidence: 99%

“…These experiments are conducted on graphene/SiC heterostructures. The graphene substrate is essential as conductive support, but it quenches the defect emission, which is slow (100 ns-1 μs) 3,29,30 , and therefore the fast exciton emission (~10 ps) dominates on graphene (Supplementary Note 5) 16,39 . For STM, all samples were prepared in-vacuo by a mild annealing step in vacuum (T annealing < 500 K) to remove adsorbates.…”

Section: Resultsmentioning

confidence: 99%

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The role of chalcogen vacancies for atomic defect emission in MoS2

et al. 2021

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For two-dimensional (2D) layered semiconductors, control over atomic defects and understanding of their electronic and optical functionality represent major challenges towards developing a mature semiconductor technology using such materials. Here, we correlate generation, optical spectroscopy, atomic resolution imaging, and ab initio theory of chalcogen vacancies in monolayer MoS2. Chalcogen vacancies are selectively generated by in-vacuo annealing, but also focused ion beam exposure. The defect generation rate, atomic imaging and the optical signatures support this claim. We discriminate the narrow linewidth photoluminescence signatures of vacancies, resulting predominantly from localized defect orbitals, from broad luminescence features in the same spectral range, resulting from adsorbates. Vacancies can be patterned with a precision below 10 nm by ion beams, show single photon emission, and open the possibility for advanced defect engineering of 2D semiconductors at the ultimate scale.

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Electronically Tunable Transparent Conductive Thin Films for Scalable Integration of 2D Materials with Passive 2D–3D Interfaces

Grünleitner

Henning

Bissolo

et al. 2022

Adv Funct Materials

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A novel transparent conductive support structure for scalable integration of 2D materials is demonstrated, providing an electronically passive 2D-3D interface while also enabling facile interfacial charge transport. This structure, which comprises an evaporated nanocrystalline carbon (nc-C) film beneath nanometer-thin atomic layer deposited AlO x , is thermally stable and allows direct chemical vapor deposition of 2D materials onto the surface. The combination of spatial uniformity, enhanced charge screening, and low interface defect concentrations yields a tenfold enhancement of MoS 2 photoluminescence intensity compared to flakes on conventional Si/SiO 2 , while also retaining the strong optical contrast for monolayer flakes. Tunneling across the ultrathin AlO x enables facile interfacial charge injection, which is utilized for high-resolution scanning electron microscopy and photoemission electron microscopy with no detectable charging. Thus, this combination of scalable fabrication and electronic conductivity across a weakly interacting 2D-3D interface opens up new opportunities for device integration and characterization of 2D materials.

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Engineering the Luminescence and Generation of Individual Defect Emitters in Atomically Thin MoS₂

Cited by 61 publications

References 49 publications

Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

The role of chalcogen vacancies for atomic defect emission in MoS2

Electronically Tunable Transparent Conductive Thin Films for Scalable Integration of 2D Materials with Passive 2D–3D Interfaces

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Engineering the Luminescence and Generation of Individual Defect Emitters in Atomically Thin MoS2

Cited by 61 publications

References 49 publications

Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride

The role of chalcogen vacancies for atomic defect emission in MoS2

Electronically Tunable Transparent Conductive Thin Films for Scalable Integration of 2D Materials with Passive 2D–3D Interfaces

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Engineering the Luminescence and Generation of Individual Defect Emitters in Atomically Thin MoS₂