Filtering the photoluminescence spectra of atomically thin semiconductors with graphene

Lorchat, Étienne; López, Luis E. Parra; Robert, Cédric; Lagarde, Delphine; Froehlicher, Guillaume; Taniguchi, Takashi; Watanabe, Kenji; Marie, X.; Berciaud, Stéphane

doi:10.1038/s41565-020-0644-2

Cited by 100 publications

(127 citation statements)

References 59 publications

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“…[ 14–21 ] The promising properties of 2D materials include attractive carrier mobility, peculiar excitonic, widely adjustable bandgaps, and light–matter interaction properties. [ 22–27 ] 2D materials have been proposed to be a potential material family for the next‐generation optoelectronic devices such as photodetector (PD), transistors, wearable devices, and ultracompact spintronics drives. [ 28–33 ] Nevertheless, the exploring of novel 2D materials is still important for broadening their applications.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances in 2D Rare Earth Materials

Chen

Han

Zhao

et al. 2020

Adv Funct Materials

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2D rare earth (RE) materials have received considerable attention in recent years due to the fascinating luminescence, magnetism, and electric properties originated from RE associated with sharp and various emission peaks, intrinsic 2D ferromagnetism, and incommensurate charge density wave. These materials might open up a new prospect in next‐generation lighting, magnetic devices, and phototransistors. Herein, a comprehensive review of 2D RE materials is presented, focusing on their recent progresses. First, the crystal structures of 2D RE materials are discussed. Then, typical synthesis methods such as mechanical exfoliation, molecular beam epitaxy, pulsed laser deposition, and chemical vapor deposition are introduced. Furthermore, various properties in luminescence, magnetism, and electronics are summarized. The recently reported RE‐based 2D novel photodetectors are outlined as three constructions: MoS2/RE, graphene/RE, and perovskite/RE, which show promising applications for both narrow and broad band detection arised from the special absorption windows of different RE elements. Finally, the conclusions and outlook of this area are proposed, such as exploring novel 2D RE compounds, improving stability, and broadening applications.

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Section: Introductionmentioning

confidence: 99%

Recent Advances in 2D Rare Earth Materials

Chen

Han

Zhao

et al. 2020

Adv Funct Materials

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“…The graphene substrate is essential as conductive support, but it quenches. the optical emission from defects (Supplementary Information S7) 31 . 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%

The role of chalcogen vacancies for atomic defect emission in MoS2

Mitterreiter¹,

Schuler

Barthelmi

et al. 2020

Preprint

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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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“…Such observations are consistent with recent works, showing that the reduction of the exciton binding energy in an atomically thin semiconductor coupled to graphene layers is readily maximized with one graphene monolayer and does not increase further if a bilayer graphene is used instead. [ 46 ] In addition, the parabolic dispersion of massive fermions in effective bilayers (Figure 1b,c) creates a finite density of states at the Dirac point, which may be sufficient to quench electron–electron interactions and the subsequent renormalization of electronic bands. Here also, additional investigations of many‐body effects are required to account for the abrupt transition between the mono‐ and bilayer cases.…”

Section: Figurementioning

confidence: 99%

Many‐Body Effects in Suspended Graphene Probed through Magneto‐Phonon Resonances

Berciaud

Потемски

Faugeras

2020

Physica Rapid Research Ltrs

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Pristine suspended monolayer graphene is a well-defined, unscreened 2D electronic system, in which a wealth of intriguing electronic, [1-5] optical, [6] and mechanical [7] properties have been uncovered. In particular, spectacular deviations from a simple one-electron picture of graphene's band structure (i.e., the Dirac cones) emerge at low carrier densities (below a few 10 11 cm À2). Due to electron-electron interactions, the velocity parameter diverges logarithmically as the Fermi energy approaches the Dirac point, [4] reaching values, well above the Fermi velocities of bulk graphite and supported graphene (%1 Â 10 6 m s À1). [8] In the presence of a transverse magnetic field B, the electronic states of graphene merge into discrete, highly degenerate Landau levels (LL). [9] The energy and lifetime of LL can be probed using magneto-transport measurements, [1,4] scanning tunnelling spectroscopy, [10] and magneto-optical spectroscopies. [9,11] Recently, micro-magneto-Raman spectroscopy (MMRS) [12-17] has been used to probe the electronic dispersion of suspended graphene layers [14] and also to demonstrate that electronic excitations between LL may be strongly affected by many-body effects. First, as B decreases, the energy of a given LL also decreases and electron-electron interactions lead to a logarithmic divergence of the corresponding velocity parameter (hereafter denoted v F for simplicity). [5,16,18] Second, inter-LL excitations lead to the formation of magneto-excitons, whose binding energies depend on the index n of the electron and hole LL they arise from, leading to n-dependent v F. [5] Thus far, Raman signatures of many-body effects have predominantly appeared on the electronic Raman scattering response of graphene [19] under a transverse magnetic field. [5,14] Recently, many-body effects have also been unveiled by monitoring magneto-phonon resonances (MPR) [12] between optically active inter-LL transitions [20] and zone-center optical phonons (i.e., Raman G-mode phonons [21]) in graphene encapsulated in hexagonal boron nitride (BN) films. [16] As recently suggested by Sonntag et al., [18] more prominent effects are expected in suspended graphene, where electron-electron interactions are minimally screened. In this letter, we report the results of MMRS measurements performed on suspended mono-to pentalayer graphene. For each number of layers N, we resolve a set of well-defined MPR. Using a single-particle effective bilayer model, we readily extract v F associated with each MPR. While a single parameter slightly above the bulk graphite value (≥ 1.05 Â 10 6 m s À1) suffices to fit all MPR for N ≥ 2 layer systems, We find that v F increases significantly up to (% 1.45 Â 10 6 m s À1 in monolayer graphene. This result is understood as a signature of enhanced many-body effects in unscreened graphene. The low-energy electronic electronic bands and magnetooptical response of mono-and N-layer graphene have been extensively discussed using an effective bilayer model. [14,22-26] To lowest order, this model uses o...

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Filtering the photoluminescence spectra of atomically thin semiconductors with graphene

Cited by 100 publications

References 59 publications

Recent Advances in 2D Rare Earth Materials

Recent Advances in 2D Rare Earth Materials

The role of chalcogen vacancies for atomic defect emission in MoS2

Many‐Body Effects in Suspended Graphene Probed through Magneto‐Phonon Resonances

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