Giant gate-tunable bandgap renormalization and excitonic effects in a 2D semiconductor

Qiu, Zhizhan; Trushin, Maxim; Fang, Hanyan; Verzhbitskiy, Ivan; Gao, Shiyuan; Laksono, Evan; Yang, Ming; Lyu, Pin; Li, Jing; Su, Jie; Telychko, Mykola; Watanabe, Kenji; Wu, Jishan; Neto, A. H. Castro; Yang, Li; Eda, Goki; Adam, Shaffique; Lu, Jiong

doi:10.1126/sciadv.aaw2347

Cited by 102 publications

(106 citation statements)

References 46 publications

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“…This shows that the amount by which the band gap can be tuned via the dielectric environment depends on the degree of internal screening in the 2D semiconductor itself. We note the band gap reduction found by Jiong et al [32], where a reduction of about 0.6 eV of the band gap was found when monolayer ReSe 2 was placed on doped graphene. We have calculated the averaged in-plane static polarizability of ReSe 2 to be 6.58 Å, corresponding to the orange dot in Fig.…”

Section: Fig 4 the Reduction Of The Qp Band Gap Of The Semiconductosupporting

confidence: 66%

“…It is clear that that the band gap reduction is stronger for 2D materials with weaker intrinsic screening suggesting that the band gap renormalization is determined by the relative change in screening provided by the graphene layer. The dashed lines are added as guides to the eye and the orange dot corresponds to previous experimental work [32] (see main text).…”

Section: Resultsmentioning

confidence: 99%

“…Subsequently, the concept of dielectric band gap engineering in 2D materials has been explored for both lateral [27,28] and vertical [29][30][31] heterostructure designs. In a recent work, Qiu et al [32] investigated the effect of dielectric screening on the quasiparticle band gap of a single layer of ReS 2 placed on top of a back-gated graphene sheet. They found that the band gap can be tuned between 2.15 and 1.93 eV when the gate voltage was varied between −63 and 45 V.…”

Section: Introductionmentioning

confidence: 99%

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Electrically controlled dielectric band gap engineering in a two-dimensional semiconductor

Riis-Jensen¹,

Lu²,

Thygesen³

2020

Phys. Rev. B

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Section: Fig 4 the Reduction Of The Qp Band Gap Of The Semiconductosupporting

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Electrically controlled dielectric band gap engineering in a two-dimensional semiconductor

Riis-Jensen¹,

Lu²,

Thygesen³

2020

Phys. Rev. B

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“…lectrostatic screening by conducting gates has previously been employed to suppress charge inhomogeneity in graphene [1][2][3] , alter its plasmon spectra 4,5 , and renormalize electronic spectra of monolayer semiconductors 6,7 . Elementary electrostatics tells us that the electron charge e placed at the distance d from a bulk conductor leads to a dipole potential evolving as 2ed 2 =r 3 at large in-plane distances r ) d, which is much weaker than the original, unscreened Coulomb potential, e=r.…”

mentioning

confidence: 99%

Control of electron-electron interaction in graphene by proximity screening

Kim

Berdyugin

et al. 2020

Nat Commun

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Electron-electron interactions play a critical role in many condensed matter phenomena, and it is tempting to find a way to control them by changing the interactions' strength. One possible approach is to place a studied system in proximity of a metal, which induces additional screening and hence suppresses electron interactions. Here, using devices with atomically-thin gate dielectrics and atomically-flat metallic gates, we measure the electronelectron scattering length in graphene and report qualitative deviations from the standard behavior. The changes induced by screening become important only at gate dielectric thicknesses of a few nm, much smaller than a typical separation between electrons. Our theoretical analysis agrees well with the scattering rates extracted from measurements of electron viscosity in monolayer graphene and of umklapp electron-electron scattering in graphene superlattices. The results provide a guidance for future attempts to achieve proximity screening of many-body phenomena in two-dimensional systems.

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“…51 , © 2019 Springer Nature excitation 40,52,53 . Recently, it was measured by scanning tunneling spectroscopy that continuous, wide range (~200 meV) tuning of the electronic bandgap and exciton binding energy could be achieved in a ReSe 2 monolayer placed on a back-gated graphene device, which was attributed to the tuning of Coulomb interactions by gatecontrolled free carriers in graphene 54 . A decreased exciton binding energy could result in a reduction of the exciton oscillator strength.…”

Section: Screening Induced By Charge Carriersmentioning

confidence: 99%

Modulation of photocarrier relaxation dynamics in two-dimensional semiconductors

2020

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Due to strong Coulomb interactions, two-dimensional (2D) semiconductors can support excitons with large binding energies and complex many-particle states. Their strong light-matter coupling and emerging excitonic phenomena make them potential candidates for next-generation optoelectronic and valleytronic devices. The relaxation dynamics of optically excited states are a key ingredient of excitonic physics and directly impact the quantum efficiency and operating bandwidth of most photonic devices. Here, we summarize recent efforts in probing and modulating the photocarrier relaxation dynamics in 2D semiconductors. We classify these results according to the relaxation pathways or mechanisms they are associated with. The approaches discussed include both tailoring sample properties, such as the defect distribution and band structure, and applying external stimuli such as electric fields and mechanical strain. Particular emphasis is placed on discussing how the unique features of 2D semiconductors, including enhanced Coulomb interactions, sensitivity to the surrounding environment, flexible van der Waals (vdW) heterostructure construction, and non-degenerate valley/spin index of 2D transition metal dichalcogenides (TMDs), manifest themselves during photocarrier relaxation and how they can be manipulated. The extensive physical mechanisms that can be used to modulate photocarrier relaxation dynamics are instrumental for understanding and utilizing excitonic states in 2D semiconductors.

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Giant gate-tunable bandgap renormalization and excitonic effects in a 2D semiconductor

Cited by 102 publications

References 46 publications

Electrically controlled dielectric band gap engineering in a two-dimensional semiconductor

Electrically controlled dielectric band gap engineering in a two-dimensional semiconductor

Control of electron-electron interaction in graphene by proximity screening

Modulation of photocarrier relaxation dynamics in two-dimensional semiconductors

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