Strain-Induced Indirect to Direct Bandgap Transition in Multilayer WSe<sub>2</sub>

Desai, Sunil R.; Seol, Gyungseon; Kang, Je-Won; Fang, Hui; Battaglia, Corsin; Kapadia, Rehan; Ager, Joel W.; Guo, Jing; Javey, Ali

doi:10.1021/nl501638a

Cited by 641 publications

(672 citation statements)

References 27 publications

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“…The PC of X 0 peak reflects a blue-shift rate of band edge of the direct K-K interband transition. [18][19][20][21] Here, the PC of X 0 at low temperature is nearly a half of the value for 2D-X 0 at room temperature reported elsewhere. 22 The discrepancy in the PC values obtained at different temperatures is at moment not understood.…”

supporting

confidence: 55%

Single photon emission from deep-level defects in monolayerWSe2

Dou

Ding

et al. 2017

Phys. Rev. B

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We report an efficient method to observe single photon emissions in monolayer WSe 2 by applying hydrostatic pressure. The photoluminescence peaks of typical two-dimensional (2D) excitons show a nearly identical pressure-induced blue-shift, whereas the energy of pressureinduced discrete emission lines (quantum emitters) demonstrates a pressure insensitive behavior.The decay time of these discrete line emissions is approximately 10 ns, which is at least one order longer than the lifetime of the broad localized (L) excitons. These characteristics lead to a conclusion that the excitons bound to deep level defects can be responsible for the observed single photon emissions.

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supporting

confidence: 55%

Single photon emission from deep-level defects in monolayerWSe2

Dou

Ding

et al. 2017

Phys. Rev. B

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“…In Refs. [88,98] electrode to apply a uniform bias voltage to the piezoelectric material. The changes in the electronic band structure, induced by the straining with the piezoelectric substrate, were also monitored by the shift of the A excitonic feature in the photoluminescence spectra.…”

Section: Homogeneous Uniaxial Strainmentioning

confidence: 99%

Strain engineering in semiconducting two-dimensional crystals

Roldán

Castellanos-Gómez

Cappelluti

et al. 2015

J. Phys.: Condens. Matter

463

428

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One of the fascinating properties of the new families of two-dimensional crystals is their high stretchability and the possibility to use external strain to manipulate, in a controlled manner, their optical and electronic properties. Strain engineering, understood as the field that study how the physical properties of materials can be tuned by controlling the elastic strain fields applied to it, has a perfect platform for its implementation in the atomically thin semiconducting materials. The object of this review is to give an overview of the recent progress to control the optical and electronics properties of 2D crystals, by means of strain engineering. We will concentrate on semiconducting layered materials, with especial emphasis in transition metal dichalcogenides (MoS2, WS2, MoSe2 and WSe2). The effect of strain in other atomically thin materials like black phosphorus, silicene, etc., is also considered. The benefits of strain engineering in 2D crystals for applications in nanoelectronics and optoelectronics will be revised, and the open problems in the field will be discussed. Contents

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“…Reflection contrast [34][35][36], transient absorption [35], time-integrated photoluminescence (PL) [37,38] and time-resolved photoluminescence (TRPL) [39,40] experiments, have been performed to study the emission properties of WSe 2 . In prior studInfluence of the substrate material on the optical properties of tungsten diselenide monolayers 2 S Lippert et al ies on WSe 2 , layers were deposited on SiO 2 /Si substrates [41,42], sapphire [43,44], graphene [45], and fused silica (quartz) [34,46] or sandwiched between layers of hBN [47].…”

Section: Introductionmentioning

confidence: 99%

Influence of the substrate material on the optical properties of tungsten diselenide monolayers

et al. 2017

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Monolayers of transition-metal dichalcogenides such as WSe 2 have become increasingly attractive due to their potential in electrical and optical applications. Because the properties of these 2D systems are known to be affected by their surroundings, we report how the choice of the substrate material affects the optical properties of monolayer WSe 2 . To accomplish this study, pump-density-dependent micro-photoluminescence measurements are performed with time-integrating and time-resolving acquisition techniques. Spectral information and power-dependent mode intensities are compared at 290K and 10K for exfoliated WSe 2 on SiO 2 /Si, sapphire (Al 2 O 3 ), hBN/Si 3 N 4 /Si, and MgF 2 , indicating substrate-dependent appearance and strength of exciton, trion, and biexciton modes. Additionally, one CVD-grown WSe 2 monolayer on sapphire is included in this study for direct comparison with its exfoliated counterpart. Time-resolved micro-photoluminescence shows how radiative decay times strongly differ for different substrate materials. Our data indicates exciton-exciton annihilation as a shortening mechanism at room temperature, and subtle trends in the decay rates in correlation to the dielectric environment at cryogenic temperatures. On the measureable time scales, trends are also related to the extent of the respective 2D-excitonic modes' appearance. This result highlights the importance of further detailed characterization of exciton features in 2D materials, particularly with respect to the choice of substrate.

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Strain-Induced Indirect to Direct Bandgap Transition in Multilayer WSe₂

Cited by 641 publications

References 27 publications

Single photon emission from deep-level defects in monolayerWSe2

Single photon emission from deep-level defects in monolayerWSe2

Strain engineering in semiconducting two-dimensional crystals

Influence of the substrate material on the optical properties of tungsten diselenide monolayers

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Strain-Induced Indirect to Direct Bandgap Transition in Multilayer WSe2

Cited by 641 publications

References 27 publications

Single photon emission from deep-level defects in monolayerWSe2

Single photon emission from deep-level defects in monolayerWSe2

Strain engineering in semiconducting two-dimensional crystals

Influence of the substrate material on the optical properties of tungsten diselenide monolayers

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Strain-Induced Indirect to Direct Bandgap Transition in Multilayer WSe₂