Computational Study of Metal Contacts to Monolayer Transition-Metal Dichalcogenide Semiconductors

Kang, Jiahao; Liu, Wei; Sarkar, Deblina; Jena, Debdeep; Banerjee, Kaustav

doi:10.1103/physrevx.4.031005

Cited by 574 publications

(916 citation statements)

References 41 publications

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“…This value significantly underestimates the electronic gap of 2.8 eV determined by more sophisticated quasi-particle (GW) calculations [6]. Interestingly, calculations with the local density approximation (LDA) [44,45] or with another exchange-correlation functional (PW91) within the generalized gradient approximation (GGA) lead to slightly (≈ 0.2 eV) larger values [46] than the 1.58 eV calculated here. Band gap underestimation is a well-known shortcoming of the LDA and GGA approaches, which can be partially remedied by including a fraction of Hartree-Fock exchange, leading to the so-called hybrid functional formalism.…”

Section: (C)contrasting

confidence: 63%

Single-layerMoS2on Au(111): Band gap renormalization and substrate interaction

et al. 2016

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The electronic structure of epitaxial single-layer MoS2 on Au(111) is investigated by angleresolved photoemission spectroscopy, scanning tunnelling spectroscopy, and first principles calculations. While the band dispersion of the supported single-layer is close to a free-standing layer in the vicinity of the valence band maximum atK and the calculated electronic band gap on Au (111) is similar to that calculated for the free-standing layer, significant modifications to the band structure are observed at other points of the two-dimensional Brillouin zone: AtΓ, the valence band maximum has a significantly higher binding energy than in the free MoS2 layer and the expected spin-degeneracy of the uppermost valence band at theM point cannot be observed. These band structure changes are reproduced by the calculations and can be explained by the detailed interaction of the out-of-plane MoS2 orbitals with the substrate.

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Section: (C)contrasting

confidence: 63%

Single-layerMoS2on Au(111): Band gap renormalization and substrate interaction

et al. 2016

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“…The band gap (calculated using the HSE functional) decreases as thickness increases, also following a linear relation with 1/n or 1/d, and becomes 0.4 eV for infinitelythick (bulk) Te, close to the experimental value 0.35 eV 28 . The VBM/CBM energy (calculated using the HSE functional) also decreases/increases linearly with 1/n or 1/d, as shown in 19 , which suggests a lower Schottky barrier for hole injection than for electron [29][30][31] . This could be one reason why Te is p-type 7 .…”

Section: Introductionmentioning

confidence: 99%

Tellurium: Fast Electrical and Atomic Transport along the Weak Interaction Direction

2018

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In anisotropic materials, the electrical and atomic transport along the weak interaction direction is usually much slower than that along the chemical bond direction. However, Te, an important semiconductor composed of helical atomic chains, exhibits nearly isotropic electrical transport between intrachain and interchain directions. Using first-principles calculations to study bulk and few-layer Te, we show that this isotropy is related to similar effective masses and potentials for charge carriers along different transport directions, benefiting from the delocalization of the lone-pair electrons. This delocalization also enhances the interchain binding, and thus facilitates diffusion of vacancies and interstitial atoms across the chains, which together with the fast intrachain diffusion enable rapid self-healing of these defects at low temperature. Interestingly, the interstitial atoms diffuse along the chain via a concerted rotation mechanism. Our work reveals the unconventional properties underlying the superior performance of Te while providing insight into the transport in anisotropic materials.

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“…The triangular shaped structures result from the initial stages of growth where threedimensional triangular islands first nucleate and grow with a (111) orientation before eventually forming a continuous coverage as more Au is deposited [11,[15][16][17]. The interface is known to be atomically smooth and only weakly bonded [15,[17][18][19] such that it is possible to drag entire Au islands across the MoS 2 surface using an STM tip [20]. Thicker films exhibit a combination of hexagonal and irregular-shaped structures such as those seen on the surface of the 20 nm film in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Instead, we turn our attention to scattering at the Au/MoS 2 interface. Recent calculations predict a narrow tunneling barrier at the Au/MoS 2 interface [18,19] that would act to hinder transmission. If our previous conclusion is correct, we would expect transmission to decrease at a greater exponential rate as the Au/MoS 2 spacing steadily increases, consistent with the sudden drop in transmission at roughly 16 nm seen in Fig.…”

Section: Substrate a Recent Density Functional Theory (Dft) Study Ofmentioning

confidence: 99%

Influence of interface coupling on the electronic properties of theAu/MoS2junction

et al. 2015

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Thin films of Au ranging from 7-24 nm were grown on MoS 2 at room temperature using thermal evaporation and studied using scanning tunneling microscopy and ballistic electron emission spectroscopy.Topographic images show the surface morphology of Au transitions from terraced triangles to a mix of terraced hexagonal and irregular-shaped structures as film thickness exceeded 16 nm. Raman spectra reveal the presence of tensile strain in the MoS 2 with thicker Au films and is likely the driving force behind this transition. All samples exhibit a Schottky barrier significantly lower than that predicted by the Schottky-Mott model due to Fermi level pinning at the interface. The pinning mechanism is thought to be caused, in part, by the presence of gap states induced by a weakening of the interlayer Mo-S bonding in the presence of the Au film. Although relatively consistent in thinner films, the Schottky barrier increases concurrently with structural changes on the surface. At the same time, transmission through the interface begins to drop at an increased exponential rate with film thickness. These observations are consistent with a widening separation between the Au and MoS 2 that would reduce the number of gap states and cause transmission through the interface to be more characteristic of quantum tunneling. An increased separation such as this could result from changes in equilibrium conditions at the interface with increasing strain.

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Computational Study of Metal Contacts to Monolayer Transition-Metal Dichalcogenide Semiconductors

Cited by 574 publications

References 41 publications

Single-layerMoS2on Au(111): Band gap renormalization and substrate interaction

Single-layerMoS2on Au(111): Band gap renormalization and substrate interaction

Tellurium: Fast Electrical and Atomic Transport along the Weak Interaction Direction

Influence of interface coupling on the electronic properties of theAu/MoS2junction

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