Emilio Scalise scite author profile

The electronic properties of two-dimensional honeycomb structures of molybdenum disulfide (MoS 2 ) subjected to biaxial strain have been investigated using first-principles calculations based on density functional theory. On applying compressive or tensile bi-axial strain on bi-layer and mono-layer MoS 2 , the electronic properties are predicted to change from semiconducting to metallic. These changes present very interesting possibilities for engineering the electronic properties of two-dimensional structures of MoS 2 .

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Electronic properties of hydrogenated silicene and germanene

Houssa

et al. 2011

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The electronic properties of hydrogenated silicene and germanene, so called silicane and germanane, respectively, are investigated using first-principles calculations based on density functional theory. Two different atomic configurations are found to be stable and energetically degenerate. Upon the adsorption of hydrogen, an energy gap opens in silicene and germanene. Their energy gaps are next computed using the HSE hybrid functional as well as the G0W0 many-body perturbation method. These materials are found to be wide band-gap semiconductors, the type of gap in silicane (direct or indirect) depending on its atomic configuration. Germanane is predicted to be a direct-gap material, independent of its atomic configuration, with an average energy gap of about 3.2 eV, this material thus being potentially interesting for optoelectronic applications in the blue/violet spectral range.

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Two‐Dimensional Si Nanosheets with Local Hexagonal Structure on a MoS₂ Surface

Chiappe¹,

Scalise

Cinquanta³

et al. 2013

Advanced Materials

331

241

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The structural and electronic properties of a Si nanosheet (NS) grown onto a MoS2 substrate by means of molecular beam epitaxy are assessed. Epitaxially grown Si is shown to adapt to the trigonal prismatic surface lattice of MoS2 by forming two-dimensional nanodomains. The Si layer structure is distinguished from the underlying MoS2 surface structure. The local electronic properties of the Si nanosheet are dictated by the atomistic arrangement of the layer and unlike the MoS2 hosting substrate they are qualified by a gap-less density of states.

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Vibrational properties of silicene and germanene

et al. 2012

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Getting through the Nature of Silicene: An sp²–sp³ Two-Dimensional Silicon Nanosheet

Cinquanta¹,

Scalise

Chiappe³

et al. 2013

J. Phys. Chem. C

172

180

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By combining experimental techniques with ab-initio density functional theory calculations, we describe the Si/Ag(111) two-dimensional system in terms of a sp 2 -sp 3 crystalline form of silicon characterized by a vertically distorted honeycomb lattice. We show that 2D sp 2 -sp 3 Si NSs are qualified by a prevailing Raman peak which can be assigned to a graphene-like E 2g vibrational mode and that highly distorted superstructures are semiconductive whereas low distorted ones behave as semimetals.

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First-principles study of strained 2D MoS2

Scalise

Houssa

Pourtois

et al. 2014

Physica E: Low-dimensional Systems and Nanostructures

122

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An electric field tunable energy band gap at silicene/(0001) ZnS interfaces

Houssa

Broek

Scalise

et al. 2013

Phys. Chem. Chem. Phys.

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The interaction of silicene, the silicon counterpart of graphene, with (0001) ZnS surfaces is investigated theoretically, using first-principles simulations. The charge transfer occurring at the silicene/(0001) ZnS interface leads to the opening of an indirect energy band gap of about 0.7 eV in silicene. Remarkably, the nature (indirect or direct) and magnitude of the energy band gap of silicene can be controlled by an external electric field: the energy gap is predicted to become direct for electric fields larger than about 0.5 V Å(-1), and the direct energy gap decreases approximately linearly with the applied electric field. The predicted electric field tunable energy band gap of the silicene/(0001) ZnS interface is very promising for its potential use in nanoelectronic devices.

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Engineering the electronic properties of silicene by tuning the composition of MoX ₂ and GaX (X = S,Se,Te) chalchogenide templates

Scalise¹,

Houssa²,

Cinquanta³

et al. 2014

2D Mater.

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By using first-principles simulations, we investigate the interaction of a 2D silicon layer with two classes of chalcogenide-layered compounds, namely MoX2 and GaX (X = S, Se, Te). A rather weak (van der Waals) interaction between the silicene layers and the chalcogenide layers is predicted. We found that the buckling of the silicene layer is correlated to the lattice mismatch between the silicene layer and the MoX2 or GaX template. The electronic properties of silicene on these different templates largely depend on the buckling of the silicene layer: highly buckled silicene on MoS2 is predicted to be metallic, while low buckled silicene on GaS and GaSe is predicted to be semi-metallic, with preserved Dirac cones at the K points. These results indicate new routes for artificially engineering silicene nanosheets, providing tailored electronic properties of this 2D layer on non-metallic substrates. These non-metallic templates also open the way to the possible integration of silicene in future nanoelectronic devices.

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Emilio Scalise

Strain-induced semiconductor to metal transition in the two-dimensional honeycomb structure of MoS2

Electronic properties of hydrogenated silicene and germanene

Two‐Dimensional Si Nanosheets with Local Hexagonal Structure on a MoS₂ Surface

Vibrational properties of silicene and germanene

Getting through the Nature of Silicene: An sp²–sp³ Two-Dimensional Silicon Nanosheet

First-principles study of strained 2D MoS2

An electric field tunable energy band gap at silicene/(0001) ZnS interfaces

Engineering the electronic properties of silicene by tuning the composition of MoX ₂ and GaX (X = S,Se,Te) chalchogenide templates

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About

Emilio Scalise

Strain-induced semiconductor to metal transition in the two-dimensional honeycomb structure of MoS2

Electronic properties of hydrogenated silicene and germanene

Two‐Dimensional Si Nanosheets with Local Hexagonal Structure on a MoS2 Surface

Vibrational properties of silicene and germanene

Getting through the Nature of Silicene: An sp2–sp3 Two-Dimensional Silicon Nanosheet

First-principles study of strained 2D MoS2

An electric field tunable energy band gap at silicene/(0001) ZnS interfaces

Engineering the electronic properties of silicene by tuning the composition of MoX 2 and GaX (X = S,Se,Te) chalchogenide templates

Contact Info

Product

Resources

About

Two‐Dimensional Si Nanosheets with Local Hexagonal Structure on a MoS₂ Surface

Getting through the Nature of Silicene: An sp²–sp³ Two-Dimensional Silicon Nanosheet

Engineering the electronic properties of silicene by tuning the composition of MoX ₂ and GaX (X = S,Se,Te) chalchogenide templates