Engineering the Structural and Electronic Phases of MoTe<sub>2</sub> through W Substitution

Rhodes, Daniel; Chenet, Daniel; Janicek, Blanka E.; Nyby, Clara; Lin, Yi; Jin, Wencan; Edelberg, Drew; Mannebach, Ehren; Finney, Nathan; Antony, Abhinandan; Schiros, Theanne; Klarr, T.; Mazzoni, A.; Chin, Matthew L.; Chiu, Yu-Che; Zheng, Wenkai; Zhang, Q. R.; Ernst, Friederike; Dadap, Jerry I.; Tong, Xiao; Ma, Junzhang; Lou, Rui; Wang, S.; Qian, Tian; Ding, H.; Osgood, Richard M.; Paley, Daniel W.; Lindenberg, Aaron M.; Huang, Pinshane Y.; Pasupathy, Abhay; Dubey, Madan; Hone, James; Balicas, Luis

doi:10.1021/acs.nanolett.6b04814

Cited by 144 publications

(151 citation statements)

References 32 publications

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“…MoTe2 is one of the few TMDCs in that it stabilizes both semiconducting and metallic polytypes, transitions between which can be further controlled by temperature, alloying, strain, and electrostatic gating [4][5][6][7][8][9][10]. 1T-MoTe2 is unstable, however-distortion of in-plane bonds gives rise to an enlarged monoclinic unit cell ( or 1T' phase) at room temperature [11].…”

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confidence: 99%

Dimensionality-driven orthorhombic MoTe2 at room temperature

Zhong

Kim

et al. 2018

Phys. Rev. B

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Abstract:We use a combination of Raman spectroscopy and transport measurements to study thin flakes of the type-II Weyl semimetal candidate MoTe2 protected from oxidation. In contrast to bulk crystals, which undergo a phase transition from monoclinic to the inversion symmetry breaking, orthorhombic phase below ~250 K, we find that in moderately thin samples below ~12 nm, a single orthorhombic phase exists up to and beyond room temperature. This could be due to the effect of c-axis confinement, which lowers the energy of an out-of-plane hole band and stabilizes the orthorhombic structure. Our results suggest that Weyl nodes, predicated upon inversion symmetry breaking, may be observed in thin MoTe2 at room temperature. Main text:

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confidence: 99%

Dimensionality-driven orthorhombic MoTe2 at room temperature

Zhong

Kim

et al. 2018

Phys. Rev. B

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“…The properties of TMDs are closely associated with the polymorphism in crystal symmetry . In MoTe 2 , the room‐temperature stable phase is hexagonal 2H ( Figure a), which displays a bandgap of ≈1 eV, appealing for flexible and transparent optoelectronics devices . Through controllable conversion from 2H to the other semimetallic phases Tʹ (monoclinic, Figure b) and T d (orthorhombic, Figure c), the semiconducting to metallic transition can be realized, which helps achieve ohmic contact in heterojunctions and make broad applications including memory and phase‐change devices .…”

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confidence: 99%

Atomic Insights into Phase Evolution in Ternary Transition‐Metal Dichalcogenides Nanostructures

Zou

Chen

Liu

et al. 2018

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Phase engineering through chemical modification can significantly alter the properties of transition-metal dichalcogenides, and allow the design of many novel electronic, photonic, and optoelectronics devices. The atomic-scale mechanism underlying such phase engineering is still intensively investigated but elusive. Here, advanced electron microscopy, combined with density functional theory calculations, is used to understand the phase evolution (hexagonal 2H→monoclinic T'→orthorhombic T ) in chemical vapor deposition grown Mo W Te nanostructures. Atomic-resolution imaging and electron diffraction indicate that Mo W Te nanostructures have two phases: the pure monoclinic phase in low W-concentrated (0 < x ≤ 10 at.%) samples, and the dual phase of the monoclinic and orthorhombic in high W-concentrated (10 < x < 90 at.%) samples. Such phase coexistence exists with coherent interfaces, mediated by a newly uncovered orthorhombic phase T '. T ', preserves the centrosymmetry of T' and provides the possible phase transition path for T'→T with low energy state. This work enriches the atomic-scale understanding of phase evolution and coexistence in multinary compounds, and paves the way for device applications of new transition-metal dichalcogenides phases and heterostructures.

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“…Phase engineering of MoTe 2 by W-substitution was revealed in the phase-diagram of the Mo 1-x W x Te 2 solid solution, which displays a semiconducting to semi metallic transition as a function of x. A small critical W concentration x c ∼ 8% was observed to stabilize the γ-phase at room temperature suggesting that crystals with x close to x c might be particularly susceptible to phase transformations induced by an externally applied electric field [73].…”

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Band Gap Engineering of Hybrid 2-D Nanomaterials Some Recent Developments

Ahmad¹

2017

MOJPS

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Successful modifications of band gaps of bulk alloy semiconductors (i.e. in binary, ternary and quaternary compounds) for electronic and optoelectronic device applications encouraged the researchers to explore similar strategies in 2D-materials involving graphene and graphene like transition metal chalcogenides and other layered materials. Being atomically thin layers, there are numerous other possibilities to explore in these 2D-materials involving lateral, vertical heterostructure formations besides substitution, and doping of other atomic species to fix their band gaps somewhere between zero of the graphene and the wide band gap, for example, of h-BN (i.e. 6eV band gap) in hybrid type h-BNC lattice. The recent developments taking place in this important area of research in band gap engineering of 2D-hybrid materials is briefly discussed in this review.

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Engineering the Structural and Electronic Phases of MoTe₂ through W Substitution

Cited by 144 publications

References 32 publications

Dimensionality-driven orthorhombic MoTe2 at room temperature

Dimensionality-driven orthorhombic MoTe2 at room temperature

Atomic Insights into Phase Evolution in Ternary Transition‐Metal Dichalcogenides Nanostructures

Band Gap Engineering of Hybrid 2-D Nanomaterials Some Recent Developments

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Engineering the Structural and Electronic Phases of MoTe2 through W Substitution

Cited by 144 publications

References 32 publications

Dimensionality-driven orthorhombic MoTe2 at room temperature

Dimensionality-driven orthorhombic MoTe2 at room temperature

Atomic Insights into Phase Evolution in Ternary Transition‐Metal Dichalcogenides Nanostructures

Band Gap Engineering of Hybrid 2-D Nanomaterials Some Recent Developments

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Engineering the Structural and Electronic Phases of MoTe₂ through W Substitution