Oxidation-Induced Topological Phase Transition in Monolayer 1T′-WTe<sub>2</sub>

Yang, Jiali; Jin, Yuhao; Xu, Wangping; Zheng, Baobing; Wang, Rui; Xu, Hu

doi:10.1021/acs.jpclett.8b01999

Cited by 23 publications

(26 citation statements)

References 47 publications

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“…A very recent study further demonstrated the out-of-plane switchable polarization in two- or three-layer WTe 2 , although WTe 2 is well-known as a topological semimetal in previous reports. − Despite the polarization that was almost negligible compared with traditional perovskite FE (3 orders of magnitude lower than BaTiO 3 ), the Curie temperature amazingly turned out to be around 350 K. The origin of such FE is still unclarified, as the vertical polarization seems to be switchable without vertical ion displacement. It was supposed in this report that the FE may origin from the electron–hole correlation rather than lattice instability, where a relative motion of the electron cloud relative to the ion core may take place .…”

mentioning

confidence: 96%

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Yang

2018

J. Phys. Chem. Lett.

238

192

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In a recent report, room-temperature vertical ferroelectricity was experimentally shown in WTe2 bilayer, while its mechanism of ferroelectric switching without vertical ion displacements remains unclarified. In this work, we reveal its origin by first-principles calculations that the polarization stems from uncompensated interlayer vertical charge transfer depending on in-plane translation, which can be switched upon interlayer sliding. The calculated results are consistent with experimental data, and a similar switching mechanism can be applied to a multilayer counterpart. Despite its small ferroelectric switching barrier and polarization, the in-plane rigidity of WTe2 layer gives rise to a high Curie temperature. A moire pattern of ferroelectric domain superlattice can be formed and tuned upon a small-angle twist of bilayer, which is unique compared with traditional ferroelectrics. Similar interlayer translational ferroelectricity may exist in a series of van der Waals bilayers or even bulk phases.

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mentioning

confidence: 96%

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Yang

2018

J. Phys. Chem. Lett.

238

192

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“…24 Particularly, 1T′-WTe 2 is even more stable than the 2H phase. 25 Various methods have been applied to tune the transition barrier between these three phases to satisfy diverse needs in multiple devices. For example, Wang et al systematically investigated the electro-chemical dynamic process of MoS 2 nanosheets upon lithium intercalation by in situ high-resolution transmission electron microscopy.…”

Section: Introductionmentioning

confidence: 99%

Strain-Controllable Phase and Magnetism Transitions in Re-Doped MoTe₂ Monolayer

Zhao

Liu

et al. 2020

J. Phys. Chem. C

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Developing approaches to effectively manipulate the magnetic states and phase transition is critical to the application of transition metal dichalcogenides (TMDs) in spintronic or phaseswitching devices. In this work, Re doping and strain engineering are combined to control the phase transition between 2H-and 1T′-MoTe 2 and to induce magnetism in the system based on density functional theory calculations. The structural transformation from 2H-to 1T′phase is predicted to occur around a doping concentration of 11%. The intrinsically nonmagnetic 2H-MoTe 2 structures with various doping concentrations become magnetic under a biaxial tensile strain, and the magnetic moment slowly increases with strain. For 1T′-MoTe 2 , only monolayers with a doping concentration of less than 10% exhibit magnetism under relatively high strain. The conversion from ionic to covalent bonding and the self-exchange mechanisms are found to be the origin of the tunable magnetic behaviors under strain. The synchronous emergence of the structural transition and magnetism in Re-doped MoTe 2 under isotropic strain offers a great possibility to design novel and tunable spintronic devices.

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“…According to XPS measurements, 22,23,26−28 the oxidation driving force are formation of WO x and TeO x on the surface of WTe 2 . Theoretical calculation 24,29 claimed the fast oxidation happens with the aid of H 2 O, which can decrease the reaction barrier. And charge depletion was found to near the O adsorption site, which may induce charge dipolar and even polarization.…”

Section: Introductionmentioning

confidence: 99%

Surface band bending in semimetal Td-WTe2

Chen

Huang

et al. 2020

Preprint

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Recently, spontaneous out-of-plane electric polarization and ferroelectric switching were found in WTe2 devices. On single crystal with ferroelectric property, a built-in electric field and corresponding band bending would be expected at the surface. However, such band bending in WTe2 hasn’t directly been observed experimentally. Here, by fitting angle-dependent X-ray photoelectron spectroscopy (XPS) spectra on WTe2 surface, we clearly observed downward band bending after slightly exposure to air, verifying appearance of surface polarization. Such band bending can’t be observed on pristine WTe2 surface and will disappear on fully oxidized sample. It suggests strong correlation between surface band bending and oxidation. Ionized donors from oxide species pinned at surface may contribute to the formation of surface band bending and polarization. Our study here offers new insight to figure out the microscopic origin of ferroelectric in WTe2.

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Oxidation-Induced Topological Phase Transition in Monolayer 1T′-WTe₂

Cited by 23 publications

References 47 publications

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Strain-Controllable Phase and Magnetism Transitions in Re-Doped MoTe₂ Monolayer

Surface band bending in semimetal Td-WTe2

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Oxidation-Induced Topological Phase Transition in Monolayer 1T′-WTe2

Cited by 23 publications

References 47 publications

Origin of Two-Dimensional Vertical Ferroelectricity in WTe2 Bilayer and Multilayer

Origin of Two-Dimensional Vertical Ferroelectricity in WTe2 Bilayer and Multilayer

Strain-Controllable Phase and Magnetism Transitions in Re-Doped MoTe2 Monolayer

Surface band bending in semimetal Td-WTe2

Contact Info

Product

Resources

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Oxidation-Induced Topological Phase Transition in Monolayer 1T′-WTe₂

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Origin of Two-Dimensional Vertical Ferroelectricity in WTe₂ Bilayer and Multilayer

Strain-Controllable Phase and Magnetism Transitions in Re-Doped MoTe₂ Monolayer