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1. Monolayer 1T-NbSe ₂ as a 2D-correlated magnetic insulator

   https://doi.org/10.1126/sciadv.abi6339  

   Liu, Mengke; Leveillee, Joshua; Lu, Shuangzan; Yu, Jia; Kim, Hyunsue; Tian, Cheng; Shi, Youguo; Lai, Keji; Zhang, Chendong; Giustino, Feliciano; et al (November 2021, Science Advances)

   Monolayer group V transition metal dichalcogenides in their 1T phase have recently emerged as a platform to investigate rich phases of matter, such as spin liquid and ferromagnetism, resulting from strong electron correlations. Newly emerging 1T-NbSe 2 has inspired theoretical investigations predicting collective phenomena such as charge transfer gap and ferromagnetism in two dimensions; however, the experimental evidence is still lacking. Here, by controlling the molecular beam epitaxy growth parameters, we demonstrate the successful growth of high-quality single-phase 1T-NbSe 2 . By combining scanning tunneling microscopy/spectroscopy and ab initio calculations, we show that this system is a charge transfer insulator with the upper Hubbard band located above the valence band maximum. To demonstrate the electron correlation resulted magnetic property, we create a vertical 1T/2H NbSe 2 heterostructure, and we find unambiguous evidence of exchange interactions between the localized magnetic moments in 1T phase and the metallic/superconducting phase exemplified by Kondo resonances and Yu-Shiba-Rusinov–like bound states. 

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2. Thickness-dependent phase transition kinetics in lithium-intercalated MoS ₂

   https://doi.org/10.1088/2053-1583/ac4e9b  

   Pondick, Joshua V; Yazdani, Sajad; Kumar, Aakash; Hynek, David J; Hart, James L; Wang, Mengjing; Qiu, Diana Y; Cha, Judy J (February 2022, 2D Materials)

   Abstract The phase transitions of two-dimensional (2D) materials are key to the operation of many devices with applications including energy storage and low power electronics. Nanoscale confinement in the form of reduced thickness can modulate the phase transitions of 2D materials both in their thermodynamics and kinetics. Here, using in situ Raman spectroscopy we demonstrate that reducing the thickness of MoS 2 below five layers slows the kinetics of the phase transition from 2H- to 1T′-MoS 2 induced by the electrochemical intercalation of lithium. We observe that the growth rate of 1T′ domains is suppressed in thin MoS 2 supported by SiO 2 , and attribute this growth suppression to increased interfacial effects as the thickness is reduced below 5 nm. The suppressed kinetics can be reversed by placing MoS 2 on a 2D hexagonal boron nitride ( h BN) support, which readily facilitates the release of strain induced by the phase transition. Additionally, we show that the irreversible conversion of intercalated 1T′-MoS 2 into Li 2 S and Mo is also thickness-dependent and the stability of 1T′-MoS 2 is significantly increased below five layers, requiring a much higher applied electrochemical potential to break down 1T′-MoS 2 into Li 2 S and Mo nanoclusters. 

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3. Interaction of Pb ²⁺ ions in water with two-dimensional molybdenum disulfide

   https://doi.org/10.1088/2515-7639/ab7ab3  

   Li, Duo O.; Gilliam, Matthew S.; Debnath, Abhishek; Chu, Ximo S.; Yousaf, Ahmed; Green, Alexander A.; Wang, Qing Hua (March 2020, Journal of Physics: Materials)

   Abstract The removal of heavy metal contaminants from water is important for public health, and recently many two-dimensional (2D) materials with high specific surface areas are being studied as promising new active components in water purification. In particular, 2D MoS₂nanosheets have been used for the removal of various heavy metals, but usually in either in complex geometries and composites, or in the chemically exfoliated metallic 1T-MoS₂phase. However, the interaction of heavy metals dissolved in water with unmodified semiconducting 2H-MoS₂is not well studied. In this paper, we report a detailed fundamental investigation of how Pb²⁺ions interact with 2H-MoS₂. We observe small solid clusters that form on the MoS₂surfaces after exposing them to Pb(NO₃)₂aqueous solutions as shown by atomic force microscopy and transmission electron microscopy, and for liquid phase exfoliated MoS₂we observe the nanosheets precipitating out of dispersion along with insoluble solid granules. We use a combination of x-ray photoelectron spectroscopy and x-ray diffraction to identify these solid clusters and granules as primarily PbSO₄with some PbMoO₄. We put forth an interaction mechanism that involves MoS₂defects acting as initiation sites for the partial dissolution in aqueous oxygenated conditions which produces MoO₄²⁻and SO₄²⁻ions to form the solids with Pb²⁺. These results are an important contribution to our fundamental understanding of how MoS₂interacts with metal ions and will influence further efforts to exploit MoS₂for water remediation applications. 

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4. Phase transition of Al ₂ O ₃ -encapsulated MoTe ₂ via rapid thermal annealing

   https://doi.org/10.1063/5.0097844  

   Sengupta, Rohan; Dangi, Saroj; Krylyuk, Sergiy; Davydov, Albert V.; Pavlidis, Spyridon (July 2022, Applied Physics Letters)

   Among group VI transition metal dichalcogenides, MoTe 2 is predicted to have the smallest energy offset between semiconducting 2H and semimetallic 1T′ states. This makes it an attractive phase change material for both electronic and optoelectronic applications. Here, we report fast, nondestructive, and full phase change in Al 2 O 3 -encapsulated 2H-MoTe 2 thin films to 1T′-MoTe 2 using rapid thermal annealing at 900 °C. Phase change was confirmed using Raman spectroscopy after a short annealing duration of 10 s in both vacuum and nitrogen ambient. No thickness dependence of the transition temperatures was observed for flake thickness ranging from 1.5 to 8 nm. These results represent a major step forward in understanding the structural phase transition properties of MoTe 2 thin films using external heating and underline the importance of surface encapsulation for avoiding thin film degradation. 

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5. Vertically Stacked 2H‐1T Dual‐Phase MoS ₂ Microstructures during Lithium Intercalation: A First Principles Study

   https://doi.org/10.1111/jace.17367  

   Parida, Shayani; Mishra, Avanish; Chen, Jie; Wang, Jin; Dobley, Arthur; Carter, C. Barry; Dongare, Avinash M. (August 2020, Journal of the American Ceramic Society)

   Abstract Layered transition‐metal dichalcogenides (TMDs) have shown promise to replace carbon‐based compounds as suitable anode materials for Lithium‐ion batteries (LIBs) owing to facile intercalation and de‐intercalation of lithium (Li) during charging and discharging, respectively. While the intercalation mechanism of Li in mono‐ and bi‐layer TMDs has’ been thoroughly examined, mechanistic understanding of Li intercalation‐induced phase transformation in bulk or films of TMDs is still largely unexplored. This study investigates possible scenarios during sequential Li intercalation and aims to gain a mechanistic understanding of the phase transformation in bulk MoS₂using density functional theory (DFT) calculations. The manuscript examines the role of concentration and distribution of Li‐ions on the formation of dual‐phase 2H‐1T microstructures that have been observed experimentally. The study demonstrates that lithiation would proceed in a systematic layer‐by‐layer manner wherein Li‐ions diffuse into successive interlayer spacings to render local phase transformation of the adjacent MoS₂layers from 2H‐to‐1T phase in the multilayered MoS₂. This local phase transition is attributed to partial ionization of Li and charge redistribution around the metal atoms and is followed by subsequent lattice straining. In addition, the stability of single‐phase vs. multiphase intercalated microstructures, and the origins of structural changes accompanying Li‐ion insertion are investigated at atomic scales. 

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