Large Excitonic Reflectivity of Monolayer<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi>MoSe</mml:mi></mml:mrow><mml:mrow><mml:mn>2</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>Encapsulated in Hexagonal Boron Nitride

Scuri, Giovanni; Zhou, You; High, Alexander; Wild, Dominik S.; Shu, Chi-Wang; Greve, Kristiaan De; Jauregui, Luis A.; Taniguchi, Takashi; Watanabe, Kenji; Kim, Philip; Lukin, Mikhail D.; Park, Hongkun

doi:10.1103/physrevlett.120.037402

Cited by 211 publications

(212 citation statements)

References 51 publications

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“…For very small γ T , γ r,0 dominates the linewidth and the absorption decreases as the TMD becomes highly reflective (corresponding to negative absorption, as seen in (Fig. 2b)) [43][44][45] . For very large γ T , γ nr and γ d dominates the linewidth and the absorption is decreased as the TMD becomes transparent.…”

Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 87%

“…We introduce an analytical approach to describe the light-exciton-cavity interaction, which is based on the semiconductor Bloch equations combined with a quantum transfer matrix method. The model takes into account the contribution of both the exciton radiative and non-radiative decay rates, γ r and γ nr , which have already been shown to affect the excitonic coherence and high reflection of monolayer TMDs [43][44][45] . In addition, we include the existence of a pure dephasing rate, γ d , to account for quantum coherence effects as part of the multiple interferences within the cavity.…”

Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 99%

“…This allows us to calculate the absorption, via the reflection operator's expectation value, taking into account the contributions of both γ r,0 (and its Purcell enhancement), γ nr , and γ d . The latter is a quantum coherent effect that is important to consider due to the multiple interferences in the cavity, making the absorption sensitive to exciton dephasing 43 .…”

Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 99%

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Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity

et al. 2020

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Excitons in monolayer transition-metal-dichalcogenides (TMDs) dominate their optical response and exhibit strong light-matter interactions with lifetime-limited emission. While various approaches have been applied to enhance light-exciton interactions inTMDs, the achieved strength have been far below unity, and a complete picture of its underlying physical mechanisms and fundamental limits has not been provided. Here, we introduce a TMD-based van der Waals heterostructure cavity that provides nearunity excitonic absorption, and emission of excitonic complexes that are observed at ultra-low excitation powers. Our results are in full agreement with a quantum theoretical framework introduced to describe the light-exciton-cavity interaction. We find that the subtle interplay between the radiative, non-radiative and dephasing decay rates plays a crucial role, and unveil a universal absorption law for excitons in 2D systems. This enhanced light-exciton interaction provides a platform for studying excitonic phase-transitions and quantum nonlinearities and enables new possibilities for 2D semiconductor-based optoelectronic devices. * These authors contributed equally †

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Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 87%

Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 99%

Section: Arxiv:190807598v6 [Physicsoptics] 9 Sep 2019mentioning

confidence: 99%

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Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity

et al. 2020

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“…As a result, X 0 and X emission dominate the PL spectrum of Mo-based TMDs [9], whereas the emission spectra of W-based TMDs display a complex series of lines stemming from X 0 , bi-excitons (XX 0 )[12-15], charged excitonic states (including X [10,16] and charged biexcitons (XX ) [12][13][14][15]), spin-dark excitons [17][18][19], defectinduced emission and exciton-phonon sidebands [20].Considerable progress has been made to determin-istically observe intrinsic TMD emission features. In particular, encapsulation of TMDs in hexagonal boron nitride (BN) films results in narrower neutral exciton linewidth [21,22], approaching the radiative limit [6,23,24], without however, getting rid of the other emission features mentioned above. Even in electrostatically gated devices tuned near the charge neutrality point, sizeable emission sidebands remain observable at energies close to the X feature, suggesting residual charge inhomogeneity [9,10] or intrinsic contributions from longer-lived exciton-phonon replicas [20].The complex emission spectra of TMD stimulate lively scientific debates.…”

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confidence: 99%

Filtering the photoluminescence spectra of atomically thin semiconductors with graphene

et al. 2020

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Atomically thin semiconductors made from transition metal dichalcogenides (TMDs) are model systems for investigations of strong light-matter interactions and applications in nanophotonics, opto-electronics and valley-tronics. However, the typical photoluminescence spectra of TMD monolayers display a large number of intrinsic and extrinsic features that are particularly challenging to decipher. On a practical level, monochromatic TMD-based emitters would be beneficial for low-dimensional devices but no solution has yet been found to meet this challenge. Here, using a counter-intuitive strategy that consists in interfacing TMD monolayers with graphene, a system known as an efficient luminescence quencher, we demonstrate bright, single and narrow-line photoluminescence arising solely from TMD neutral excitons. This observation stems from two effects: (i) complete neutralization of the TMD by the adjacent graphene leading to the absence of optical features from charged excitons (ii) selective non-radiative transfer of TMD excitons to graphene, that is sufficiently rapid to quench radiative recombination of long-lived excitonic species without significantly affecting bright excitons, which display much shorter, picosecond radiative lifetimes at low temperatures. Our approach is systematically applied to four tungsten and molybdenumbased TMDs and establishes TMD/graphene heterostructures as a unique set of opto-electronic building blocks. Graphene not only endows TMDs monolayers with superior optical performance and enhanced photostability but also provides an excellent electrical contact, suitable for TMDbased electroluminescent systems emitting visible and near-infrared photons at near THz rate with linewidths approaching the lifetime limit.TMD monolayers (thereafter simply denoted TMD), such as MoS 2 , MoSe 2 , WS 2 , WSe 2 are direct-bandgap semiconductors [1,2], featuring short Bohr radii, large exciton binding energy (near 500 meV [3]) and picosecond excitonic radiative lifetimes at low temperature [4][5][6], all arising from their strong 2D Coulomb interactions, reduced dielectric screening and large effective masses [3,7]. Since the first investigations of light emission from TMDs, it has been clear that their lowtemperature spectra was composed of at least two prominent features, stemming from bright neutral excitons (X 0 ) and charged excitons (trions, X ) [8-10] endowed with a binding energy of typically 20 to 40 meV relative to X 0 . Among the vast family of TMDs, one may distinguish between so-called dark and bright materials [11]. In the case of Molybdenum based-TMDs, X 0 is the lowest lying excitonic state, resulting in rather intense emission at low temperature, whereas, a spin-dark state lies lower than X 0 in Tungsten-based TMDs. As a result, X 0 and X emission dominate the PL spectrum of Mo-based TMDs [9], whereas the emission spectra of W-based TMDs display a complex series of lines stemming from X 0 , bi-excitons (XX 0 )[12-15], charged excitonic states (including X [10,16] and charged biexcitons (...

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“…Thus, in this region of frequencies, the SQD supercrystal operates as a perfect mirror. It has been reported recently that an atomically thin mirror can be realized based on a monolayer of MoSe 2 [71,72]. SQD supercrystals represent yet another class of nanoscopically thin reflectors.…”

Section: Reflectancementioning

confidence: 99%

Nonlinear optical response of a two-dimensional quantum-dot supercrystal: Emerging multistability, periodic and aperiodic self-oscillations, chaos, and transient chaos

et al. 2019

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We conduct a theoretical study of the nonlinear optical response of a two-dimensional semiconductor quantum dot supercrystal subjected to a quasi-resonant continuous wave excitation. A constituent quantum dot is modeled as a three-level ladder-like system (comprising the ground, the one-exciton, and the bi-exction states). To study the stationary response of the supercrystal, we propose an exact linear parametric method of solving the nonlinear steady-state problem, while to address the supercrystal optical dynamics qualitatively, we put forward a novel method to calculate the bifurcation diagram of the system. Analyzing the dynamics, we demonstrate that the supercrystal can exhibit multistability, periodic and aperiodic self-oscillations, and chaotic behavior, depending on parameters of the supercrystal and excitation conditions. The effects originate from the interplay of the intrinsic nonlinearity of quantum dots and the retarded inter-dot dipole-dipole interaction. The latter provides a positive feedback which results in the exotic supercrystal optical dynamics. These peculiarities of the supercrystal optical response open up a possibility for all-optical applications and devices. In particular, an all-optical switch, a tunable generator of THz pulses (in self-oscillating regime), a noise generator (in chaotic regime), and a tunable bistable mirror can be designed. a b c FIG. 1. PbSe rocksalt 2D nanostructures with (a) honeycomb and (b) square lattice symmetry, (c) -CdSe nanostructure with a compressed zincblende and slightly distorted square lattices (scale bars, 50 nm). Insets show the electrodiffractograms in the [111] (a) and [100] (b,c) projections. The figure is from Ref. [7].linearity of the layer is ensured by the fact that two-level emitters are nonlinear systems. The positive feedback originates from the secondary field, which is generated by the emitters themselves; this is the so-called intrinsic feedback, i.e., here a cavity (external feedback) is not required.A two-dimensional (2D) semiconductor quantum dot (SQD) supercrystal represents a limiting case of a thin layer. In this paper, we conduct a theoretical study of the nonlinear optical response of such a system. A single SQD is considered as a point-like system with three consecutive levels of the ground, one-exciton, and bi-arXiv:1910.02553v1 [physics.optics]

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Large Excitonic Reflectivity of MonolayerMoSe2Encapsulated in Hexagonal Boron Nitride

Cited by 211 publications

References 51 publications

Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity

Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity

Filtering the photoluminescence spectra of atomically thin semiconductors with graphene

Nonlinear optical response of a two-dimensional quantum-dot supercrystal: Emerging multistability, periodic and aperiodic self-oscillations, chaos, and transient chaos

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Large Excitonic Reflectivity of MonolayerMoSe2Encapsulated in Hexagonal Boron Nitride

Cited by 211 publications

References 51 publications

Near-Unity Light Absorption in a Monolayer WS2 Van der Waals Heterostructure Cavity

Near-Unity Light Absorption in a Monolayer WS2 Van der Waals Heterostructure Cavity

Filtering the photoluminescence spectra of atomically thin semiconductors with graphene

Nonlinear optical response of a two-dimensional quantum-dot supercrystal: Emerging multistability, periodic and aperiodic self-oscillations, chaos, and transient chaos

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Product

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Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity

Near-Unity Light Absorption in a Monolayer WS₂ Van der Waals Heterostructure Cavity