Dark exciton anti-funneling in atomically thin semiconductors

Rosati, Roberto; Schmidt, Robert; Brem, Samuel; Perea‐Causín, Raül; Niehues, Iris; Kern, Johannes; Preuß, Johann A.; Schneider, Robert; Vasconcellos, Steffen Michaelis de; Bratschitsch, Rudolf; Malić, Ermin

doi:10.1038/s41467-021-27425-y

Cited by 52 publications

(48 citation statements)

References 47 publications

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“…This feature may arise from regions of compressive strain between closely spaced nanobubbles, which carries an opposite effect to tensile strain (raised KK and lowered KQ exciton energies) ,, and could lead to dark-state trapping that would explain the absence of this feature in the PL image. Similarly, recent work suggests that momentum-dark excitons experience antifunneling (i.e., move away) from tensile strain regions, which may explain our observation of trapped momentum-indirect excitons between closely spaced strain nanobubbles.…”

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confidence: 78%

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Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Cheng

et al. 2022

Nano Lett.

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The optoelectronic and transport properties of two-dimensional transition metal dichalcogenide semiconductors (2D TMDs) are highly susceptible to external perturbation, enabling precise tailoring of material function through post-synthetic modifications. Here we show that nanoscale inhomogeneities known as nanobubbles can be used for both strain and, less invasively, dielectric tuning of exciton transport in bilayer tungsten disulfide (WSe2). We use ultrasensitive spatiotemporally resolved optical scattering microscopy to directly image exciton transport, revealing that dielectric nanobubbles are surprisingly efficient at funneling and trapping excitons at room temperature, even though the energies of the bright excitons are negligibly affected. Our observations suggest that exciton funneling in dielectric inhomogeneities is driven by momentum-indirect (dark) excitons whose energies are more sensitive to dielectric perturbations than bright excitons. These results reveal a new pathway to control exciton transport in 2D semiconductors with exceptional spatial and energetic precision using dielectric engineering of dark state energetic landscapes. Main text:Two-dimensional transition metal dichalcogenide semiconductors (2D TMDs) are van der Waals materials that hold great promise for nanoscale optoelectronics thanks to their strong light-matter interactions even at the atomically-thin limit. The optoelectronic properties of 2D TMDs are in large part governed by their Coulomb-bound electron-hole pairs (excitons), with relatively large binding energies of up to hundreds of milli-electronvolts (meV) due to weak out-of-plane dielectric screening. [1][2][3][4][5][6] Unlike free charges, excitons are charge neutral and are therefore difficult to manipulate with external electric fields in electronic devices. [7][8][9] Therefore, the transport properties of excitons are largely dictated by random, diffusive motion with no long-range directionality, limiting their use as information and energy carriers. Finding new ways to manipulate exciton transport in 2D TMDs without radically altering other material properties would result in excitonic devices that combine strong light-matter interactions and precise control over energy and information flow in atomically thin materials.An attractive route to controlling the properties of 2D TMDs is to leverage their extreme sensitivity to extrinsic factors such as strain, 10-21 and dielectric screening by the environment (Figure 1a), 5,[22][23][24][25][26] enabling post-synthetic tuning of their optoelectronic and transport properties. For example, tensile strain reduces the optical transition energy of 2D TMDs; 16,18,27,28 localized strain regions thus create energy gradients that can funnel and trap excitons in nanoscale low-energy sites, a process that was leveraged to create long-lived quantum emitters. 14,[29][30][31][32][33] Strain engineering, however, is difficult to control over macroscopic scales and can introduce undesired disorder.A less invasive and in principle more contr...

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confidence: 78%

“…Similarly, recent work suggests that momentum-dark excitons experience antifunneling (i.e. move away) from tensile strain regions, 69 which may explain our observation of trapped momentum-indirect excitons between closely-spaced strain nanobubbles.…”

supporting

confidence: 74%

Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Cheng

et al. 2022

Nano Lett.

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“…The spatiotemporal dynamics of excitons can be accessed through the temporal evolution of the exciton Wigner function [36][37][38], which is directly extracted from the Heisenberg equation of motion for the off-diagonal density matrix X † Q X Q . Extending the approach introduced by Hess and Kuhn [39,40] to excitons, we can quantitatively describe the spatiotemporal evolution of the interlayer exciton density n(r, t) through the following drift-diffusion equation: ṅ(r, t) = ∇ • (D(n(r, t))∇n(r, t)) with…”

Section: Coulomb-driven Exciton Propagationmentioning

confidence: 99%

Microscopic origin of anomalous interlayer exciton transport in van der Waals heterostructures

Erkensten,

Brem,

Perea-Causin

et al. 2022

Preprint

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Van der Waals heterostructures constitute a platform for investigating intriguing many-body quantum phenomena. In particular, transition-metal dichalcogenide (TMD) hetero-bilayers host long-lived interlayer excitons which exhibit permanent out-of-plane dipole moments. Here, we develop a microscopic theory for interlayer exciton-exciton interactions including both the dipolar nature of interlayer excitons as well as their fermionic substructure, which gives rise to an attractive fermionic exchange. We find that these interactions contribute to a drift force resulting in highly non-linear exciton propagation at elevated densities in the MoSe2-WSe2 heterostructure. We show that the propagation can be tuned by changing the number of hBN spacers between the TMD layers or by adjusting the dielectric environment. In particular, although counter-intuitive, we reveal that interlayer excitons in free-standing samples propagate slower than excitons in hBN-encapsulated TMDs -due to an enhancement of the net Coulomb-drift with stronger environmental screening. Overall, our work contributes to a better microscopic understanding of the interlayer exciton transport in technologically promising atomically thin semiconductors.

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“…Two-dimensional (2D) single-layer transition metal dichalcogenide (1L-TMD) semiconductors host intense light–matter interactions that can be tailored on the nanoscale for optoelectronic and quantum technologies. − Top-down perturbations such as strain or modified dielectric screening can effectuate localized states to generate quantum states of light, − control the 2D diffusion of excited states, , enhance light–matter interactions, , alter charge separation dynamics, and engineer model many-body physical systems . From the bottom-up, material stoichiometry can be tailored through the introduction of defects, ,, interfaces in lateral heterostructures, − or alloying, , providing additional opportunities to tune electronic structure and optoelectronic phenomena.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Analysis of the Nanoscale Composition, Tip-Enhanced Raman Spectroscopy, and Electronic Properties of Alloys in 2D MoS₂–WS₂ Heterostructures

et al. 2022

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Recent studies on atomically thin lateral heterostructures have demonstrated the formation of complex interfaces that can be exploited for tailoring the properties of 2D semiconductor systems for optoelectronic applications. In order to understand the compositional disorder and the resulting optical and electronic properties at these interfaces, tip-enhanced Raman scattering (TERS) imaging and spectroscopy have been used to characterize 2D lateral heterostructures at different sites across the interface, showing a continuous evolution of the Raman-active modes when transitioning from one pristine material to the other. Here, we use density functional theory (DFT) for calculating the evolution of vibrational modes, nonresonant Raman spectra, optical absorption, and electronic structure of 1L-MoS2, WS2, and Mo x W1–x S2 alloys. The calculations reproduce the evolution of the Raman modes observed in the TERS measurements, explicitly confirm the extended alloyed nature of the heterostructure interface, and provide a direct mapping of the TERS spectra to local nanoscale alloy compositions. We further elucidate how S vacancies activate a defect mode in these systems and how the mode evolves with composition, providing a second direct comparison to the nonresonant TERS measurements. Leveraging the explicit determination of the composition, we calculate how the realistic interfacial composition affects the band alignment between the two 2D materials. Our study serves as a roadmap for how the same computational approach can predict the compositional-dependent properties of additional lateral heterostructures, providing a valuable resource for quantitatively interpreting state-of-the-art nanoscale characterization measurements such as TERS imaging and spectroscopy.

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Dark exciton anti-funneling in atomically thin semiconductors

Cited by 52 publications

References 47 publications

Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Microscopic origin of anomalous interlayer exciton transport in van der Waals heterostructures

Theoretical Analysis of the Nanoscale Composition, Tip-Enhanced Raman Spectroscopy, and Electronic Properties of Alloys in 2D MoS₂–WS₂ Heterostructures

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Dark exciton anti-funneling in atomically thin semiconductors

Cited by 52 publications

References 47 publications

Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Dark-Exciton Driven Energy Funneling into Dielectric Inhomogeneities in Two-Dimensional Semiconductors

Microscopic origin of anomalous interlayer exciton transport in van der Waals heterostructures

Theoretical Analysis of the Nanoscale Composition, Tip-Enhanced Raman Spectroscopy, and Electronic Properties of Alloys in 2D MoS2–WS2 Heterostructures

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Product

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Theoretical Analysis of the Nanoscale Composition, Tip-Enhanced Raman Spectroscopy, and Electronic Properties of Alloys in 2D MoS₂–WS₂ Heterostructures