Atlas for the properties of elemental two-dimensional metals

Nevalaita, Janne; Koskinen, Pekka

doi:10.1103/physrevb.97.035411

Cited by 95 publications

(149 citation statements)

References 57 publications

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Section: Synthesis Of Elemental 2d Materialsmentioning

confidence: 99%

“…Mater. 2020, 32,1904302 insulating behavior (see below) with a predicted spin-orbit monolayer bandgap of ≈0.3 eV [26,52] and measured bandgap of 0.67 eV, [26] which disappears in multilayer bismuthene as it becomes metallic. In group VI elements, αand β-tellurene (see Figure 2) has been predicted to have a "nearly direct" and direct bandgap of 0.75 and 1.47 eV, respectively.…”

Section: Unique Properties Of Elemental 2d Materialsmentioning

confidence: 99%

“…While many of these were hypothesized to exist prior to the “reawakening” of 2D materials triggered by the initial work on graphene, recent work in the 2D materials field has shaped the future of these atomically thin materials. Last, note that this review discussion focuses specifically on the main group elements and does not explicitly discuss 2D elemental transition metals, which were reviewed elsewhere recently …”

Section: Introductionmentioning

confidence: 99%

“…Last, note that this review discussion focuses specifically on the main group elements and does not explicitly discuss 2D elemental transition metals, which were reviewed elsewhere recently. [5,32] Motivated by recent advances in the exciting class of main group elemental materials, herein we review the application literature to date, connect the crystal structure of various elemental 2D materials to their measured/predicted properties, and identify their strengths and weaknesses for applications including electronics, spintronics, optoelectronics, energy conversion, and more.…”

Section: Introductionmentioning

confidence: 99%

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Emerging Applications of Elemental 2D Materials

et al. 2019

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As elemental main group materials (i.e., silicon and germanium) have dominated the field of modern electronics, their monolayer 2D analogues have shown great promise for next‐generation electronic materials as well as potential game‐changing properties for optoelectronics, energy, and beyond. These atomically thin materials composed of single atomic variants of group III through group VI elements on the periodic table have already demonstrated exciting properties such as near‐room‐temperature topological insulation in bismuthene, extremely high electron mobilities in phosphorene and silicone, and substantial Li‐ion storage capability in borophene. Isolation of these materials within the postgraphene era began with silicene in 2010 and quickly progressed to the experimental identification or theoretical prediction of 15 of the 18 main group elements existing as solids at standard pressure and temperatures. This review first focuses on the significance of defects/functionalization, discussion of different allotropes, and overarching structure–property relationships of 2D main group elemental materials. Then, a complete review of emerging applications in electronics, sensing, spintronics, plasmonics, photodetectors, ultrafast lasers, batteries, supercapacitors, and thermoelectrics is presented by application type, including detailed descriptions of how the material properties may be tailored toward each specific application.

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Section: Synthesis Of Elemental 2d Materialsmentioning

confidence: 99%

Section: Unique Properties Of Elemental 2d Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Emerging Applications of Elemental 2D Materials

et al. 2019

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“…Fortunately, more and more atomic thickness spontaneous electric polarization has been discovered in ionic compound monolayer with the puckered lattice structure. [16,17] Among elemental 2D materials, group-VI elements have been predicted and successfully fabricated at last year. [4][5][6][7] Fascinatingly more, ferroelectricity was also discovered in the 2D elemental materials, such as phosphorene nanoribbons, [8] group-V (As, Sb, Bi) monolayer [9] and tellurium multilayers, [10] which was previously thought impossible because of the stabilized high symmetry in elemental bulk structures and the equal distribution of charge per atom.…”

mentioning

confidence: 99%

High Bipolar Conductivity and Robust In‐Plane Spontaneous Electric Polarization in Selenene

Wang

Tang

Jiang

et al. 2018

Adv Elect Materials

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perovskite films. Fortunately, more and more atomic thickness spontaneous electric polarization has been discovered in ionic compound monolayer with the puckered lattice structure. For example, atomic thickness ferroelectricity has been found in monolayer chalcogenides: M (1) X, M (2) X 2 , and M 2 (3) X 3 (M (1) = Ge, Sn; M (2) = Mo, W; M (3) = Al, Ga, In; X = S, Se, Te). [4][5][6][7] Fascinatingly more, ferroelectricity was also discovered in the 2D elemental materials, such as phosphorene nanoribbons, [8] group-V (As, Sb, Bi) monolayer [9] and tellurium multilayers, [10] which was previously thought impossible because of the stabilized high symmetry in elemental bulk structures and the equal distribution of charge per atom. In other words, bulk element cannot satisfy the two main mechanisms of ferroelectric polarization: ion-displacement and electronic polarization. Therefore, the study of elemental ferroelectricity involved in structural reconstruction is a fundamental question and will undoubtedly expand the application of ferroelectrics in device miniaturization.In the last decade, intensive efforts have been devoted to discover the potential 2D materials for the application of micro-nano electronic devices. [11][12][13][14][15] Common 2D materials have a layered 3D structure with covalently bonded, atomically thin layers held together by weak van der Waals forces. Through high-throughput computations, however, more than a thousand 2D materials with various functions have been verified or predicted, even including elemental 2D metals. [16,17] Among elemental 2D materials, group-VI elements have been predicted and successfully fabricated at last year. [18][19][20][21] In the new study, Jia and co-workers point out the underlying formation mechanism of tellurene is inherently rooted in the multi valency nature of Te, and further predict the importance of multivalency in the layering behavior of Se. [18] Motivated by this discovery, we have performed a systematic densityfunctional study on various dimension elemental tellurium, and found that the atomic structure and electronic properties of 2D monolayers and bilayers of tellurene close related to the multivalency of Te. [22] In this paper, we found that the charge transfer from the central to the outer atoms amounts to 0.18 and 0.04 e in aand β-Se, respectively. Se has the multivalent nature with both metal and nonmetal characteristics as the previously reported. In addition, we have demonstrated that monolayer a-Se possesses a rather high carrier mobility, Selenene has been predicted as a new member of an atomically thin 2D crystalline material family as of last year. With first principle calculations, two different stable phases of selenene, one with the 1T-MoS 2 -like structure (α-Se) and the other with alternating arrangement structure of deformed four-membered and six-membered rings (b-Se) are identified. Further research indicates that monolayer α-Se exhibits excellent bipolar conductivity, possessing rather high hole mobility close to that of graphene,...

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Proximity‐Induced Topological Transition and Strain‐Induced Charge Transfer in Graphene/MoS ₂ Bilayer Heterostructures

Singh

Alsharari

Ulloa

et al. 2019

Handbook of Graphene

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Graphene/MoS 2 heterostructures are formed by combining the nanosheets of graphene and monolayer MoS 2 . The electronic features of both constituent monolayers are rather well-preserved in the resultant heterostructure due to the weak van der Waals interaction between the layers. However, the proximity of MoS 2 induces strong spin orbit coupling effect of strength ∼1 meV in graphene, which is nearly three orders of magnitude larger than the intrinsic spin orbit coupling of pristine graphene. This opens a bandgap in graphene and further causes anticrossings of the spin-nondegenerate bands near the Dirac point. Lattice incommensurate graphene/MoS 2 heterostructure exhibits interesting moiré patterns which have been observed in experiments. The electronic bandstructure of heterostructure is very sensitive to biaxial strain and interlayer twist. Although the Dirac cone of graphene remains intact and no charge-transfer between graphene and MoS 2 layers occurs at ambient conditions, a strain-induced charge-transfer can be realized in graphene/MoS 2 heterostructure. Application of a gate voltage reveals the occurrence of a topological phase transition in graphene/MoS 2 heterostructure. In this chapter, we discuss the crystal structure, interlayer effects, electronic structure, spin states, and effects due to strain and substrate proximity on the electronic properties of graphene/MoS 2 heterostructure. We further present an overview of the distinct topological quantum phases of graphene/MoS 2 heterostructure and review the recent advancements in this field.

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Atlas for the properties of elemental two-dimensional metals

Cited by 95 publications

References 57 publications

Emerging Applications of Elemental 2D Materials

Emerging Applications of Elemental 2D Materials

High Bipolar Conductivity and Robust In‐Plane Spontaneous Electric Polarization in Selenene

Proximity‐Induced Topological Transition and Strain‐Induced Charge Transfer in Graphene/MoS ₂ Bilayer Heterostructures

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Atlas for the properties of elemental two-dimensional metals

Cited by 95 publications

References 57 publications

Emerging Applications of Elemental 2D Materials

Emerging Applications of Elemental 2D Materials

High Bipolar Conductivity and Robust In‐Plane Spontaneous Electric Polarization in Selenene

Proximity‐Induced Topological Transition and Strain‐Induced Charge Transfer in Graphene/MoS 2 Bilayer Heterostructures

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Product

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Proximity‐Induced Topological Transition and Strain‐Induced Charge Transfer in Graphene/MoS ₂ Bilayer Heterostructures