Renormalization of the quasiparticle band gap in doped two-dimensional materials from many-body calculations

Gao, Shiyuan; Yang, Li

doi:10.1103/physrevb.96.155410

Cited by 78 publications

(61 citation statements)

References 46 publications

(53 reference statements)

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“…This behavior resembles the renormalization of the band gap due to freecarrier screening predicted in Ref. 35 .…”

Section: Doping Dependence Of Electronic Structuresupporting

confidence: 81%

“…In comparing features between photoemission, tunneling, optical and transport measurements, it is a challenge to account for differences in sample quality, dielectric environment, gate voltage and temperature [32][33][34][35][36] . An advantage of our technique is that these differences can be eliminated, since the same devices are also suitable for optical spectroscopy, and in principle for transport studies, which can be done under exactly the same conditions as the ARPES measurements.…”

Section: Doping Dependence Of Electronic Structurementioning

confidence: 99%

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Visualizing electrostatic gating effects in two-dimensional heterostructures

Nguyen

Teutsch

Wilson

et al. 2019

Nature

164

154

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The ability to directly observe electronic band structure in modern nanoscale field-effect devices could transform understanding of their physics and function. One could, for example, visualize local changes in the electrical and chemical potentials as a gate voltage is applied. One could also study intriguing physical phenomena such as electrically induced topological transitions and many-body spectral reconstructions. Here we show that submicron angle-resolved photoemission (-ARPES) applied to two-dimensional (2D) van der Waals heterostructures affords this ability. In graphene devices, we observe a shift of the chemical potential by 0.6 eV across the Dirac point as a gate voltage is applied. In several 2D semiconductors we see the conduction band edge appear as electrons accumulate, establishing its energy and momentum, and observe significant band-gap renormalization at low densities. We also show that -ARPES and optical spectroscopy can be applied to a single device, allowing rigorous study of the relationship between gate-controlled electronic and excitonic properties.Angle resolved photoemission spectroscopy (ARPES), in which the energy and momentum of photoemitted electrons are measured from a sample subjected to a spectrally narrow ultraviolet or X-ray excitation, is a powerful technique that yields the momentum-dependent single-electron band structure and chemical potential in a solid with essentially no assumptions. It probes only electron states near the surface, and so cannot be applied to conventional semiconductor devices. It is, however, very effective when applied to 2D materials and has been used extensively to study the bands in graphene 1 , monolayer transition metal dichalcogenides 2-7 , and others 8,9 . Furthermore, µ-ARPES (with a micron-scale beam spot) can be performed 10 on 2D heterostructures (2DHSs) 11 made of stacked exfoliated 2D materials 12-14 , suggesting the possibility of monitoring electronic structure during actual device operation. We demonstrate here that momentum-resolved electronic spectra can indeed be obtained during reversible electrostatic gating, enabling direct visualization of chemical potential shifts and band structure changes controlled by the gate electric field.A limitation of ARPES is that it probes only occupied electron states, and so a semiconductor must first be electron-doped in order to obtain a signal from the conduction band. The usual approach is to deposit alkali metal atoms 1-7,15 which act as an n-type dopant, but this has several limitations: the density cannot be controlled accurately; it can only be reversed by high-temperature annealing; it introduces disorder through the random positions of the dopants; and it chemically perturbs the electronic structure in ways that are hard to calculate. Electrostatic doping has none of these disadvantages, and the accessible carrier densities are most relevant to practical devices.We first validate our technique using graphene, and then go on to apply it to the 2D transition metal dichalcogenide (TMD) sem...

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“…This behavior resembles the renormalization of the band gap due to freecarrier screening predicted in Ref. 35 .…”

Section: Doping Dependence Of Electronic Structuresupporting

confidence: 81%

Section: Doping Dependence Of Electronic Structurementioning

confidence: 99%

Visualizing electrostatic gating effects in two-dimensional heterostructures

Nguyen

Teutsch

Wilson

et al. 2019

Nature

164

154

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“…All these conclusions are fully consistent with what is known about monolayers of semiconducting TMDs. The energy difference ΔE ΓK reported in Table I from ARPES measurements is consistent with having only the K valley occupied upon accumulation of a density of holes reaching up to about 5 × 10 13 cm −2 [64,75,76]. Similarly, although no sufficiently systematic ARPES study of the conduction band of monolayer TMDs has been reported yet, analogous measurements on the doped surface of the bulk [77] (where doping should be limited to the first few layers) or monolayer [60] WSe 2 have shown that it is relatively easy to populate both the K and Q valleys in the conduction band (i.e., ΔE KQ in monolayer WSe 2 is significantly smaller than ΔE ΓK ; see Table I).…”

Section: Theoretical Analysissupporting

confidence: 68%

Enhanced Electron-Phonon Interaction in Multivalley Materials

et al. 2019

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We report a combined experimental and theoretical investigation that reveals a new mechanism responsible for the enhancement of electron-phonon coupling in doped semiconductors in which multiple inequivalent valleys are simultaneously populated. Using Raman spectroscopy on ionic-liquid-gated monolayer and bilayer MoS 2 , WS 2 , and WSe 2 over a wide range of electron and hole densities, we find that phonons with a dominant out-of-plane character exhibit strong softening upon electron accumulation while remaining unaffected upon hole doping. This unexpected-but very pronounced-electron-hole asymmetry is systematically observed in all monolayers and bilayers. By performing first-principles simulations, we show that the phonon softening occurs when multiple inequivalent valleys are populated simultaneously. Accordingly, the observed electron-hole asymmetry originates from the much larger energy separation between valleys in the valence bands-as compared to the conduction band-that prevents the population of multiple valleys upon hole accumulation. We infer that the enhancement of the electron-phonon coupling occurs because the population of multiple valleys acts to strongly reduce the efficiency of electrostatic screening for those phonon modes that cause the energy of the inequivalent valleys to oscillate out of phase. This robust mechanism is likely to play an important role in several physical phenomena, possibly including the occurrence of superconductivity in different transition metal dichalcogenides.

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“…On the other hand, free carriers in both ReSe 2 and adjacent graphene can, in principle, contribute to the renormalization of E g and tunable E b in single-layer ReSe 2 . It has been predicted that E g of a free-standing 2D semiconductor can be substantially reduced because of the presence of free carriers ( 31 , 32 ). Further, the dominant contribution to the QP bandgap renormalization in these systems is predicted to arise from the Coulomb-hole self-energy and screened-exchange self-energy ( 31 ).…”

Section: Resultsmentioning

confidence: 99%

“…It has been predicted that E g of a free-standing 2D semiconductor can be substantially reduced because of the presence of free carriers ( 31 , 32 ). Further, the dominant contribution to the QP bandgap renormalization in these systems is predicted to arise from the Coulomb-hole self-energy and screened-exchange self-energy ( 31 ). However, a detailed analysis of the experimental data reveals that the renormalization of E g and tunable E b is not likely to arise from the presence of free carriers in ReSe 2 .…”

Section: Resultsmentioning

confidence: 99%

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

et al. 2019

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Understanding the remarkable excitonic effects and controlling the exciton binding energies in two-dimensional (2D) semiconductors are crucial in unlocking their full potential for use in future photonic and optoelectronic devices. Here, we demonstrate large excitonic effects and gate-tunable exciton binding energies in single-layer rhenium diselenide (ReSe2) on a back-gated graphene device. We used scanning tunneling spectroscopy and differential reflectance spectroscopy to measure the quasiparticle electronic and optical bandgap of single-layer ReSe2, respectively, yielding a large exciton binding energy of 520 meV. Further, we achieved continuous tuning of the electronic bandgap and exciton binding energy of monolayer ReSe2 by hundreds of milli–electron volts through electrostatic gating, attributed to tunable Coulomb interactions arising from the gate-controlled free carriers in graphene. Our findings open a new avenue for controlling the bandgap renormalization and exciton binding energies in 2D semiconductors for a wide range of technological applications.

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Renormalization of the quasiparticle band gap in doped two-dimensional materials from many-body calculations

Cited by 78 publications

References 46 publications

Visualizing electrostatic gating effects in two-dimensional heterostructures

Visualizing electrostatic gating effects in two-dimensional heterostructures

Enhanced Electron-Phonon Interaction in Multivalley Materials

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

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