Multinary Alloys Based on III-V Semiconductors

Tomashyk, Vasyl

doi:10.1201/9780429055348

Cited by 2 publications

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“…The 12 × 12 × 12 k−grids over the first Brillouin zone (BZ) with the energy cut-off of 400 eV are used in the self-consistent calculations. The lattice structure and space group of TlCd 2 Te 4 is obtained from previous experiments [23]. Then, the lattice parameters and positions of ions are optimized until the residual atomic forces are less than 0.03 eV/Å.…”

Section: Methodsmentioning

confidence: 99%

“…The multinary semiconductor alloy TlCd 2 Te 4 has been synthesized by previous experiments [23]. Based on experimental results, TlCd 2 Te 4 has space group I 4 (#82) with thiogallate structure (defect-chalcopyrite structure, also presented in ordered-vacancy compounds of AB 2 X 4 [36]), which lacks the inversion symmetry while keeps an S The band structure of TlCd 2 Te 4 along high-symmetry lines in Brillouin zone (BZ) (Figure 1c) calculated using LDA is shown in Figure 1f.…”

Section: Electronic Structuresmentioning

confidence: 99%

“…In this work, using first-principles calculations based on density functional theory (DFT), we study the multinary semiconductor alloy material TlCd 2 Te 4 , which has been synthesized by previous experiments [23]. Two TFFs and nodal-line fermions in TlCd 2 Te 4 stemmed from the S 4 improper rotational symmetry are demonstrated.…”

Section: Introductionmentioning

confidence: 99%

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Threefold Fermions, Weyl Points, and Superconductivity in the Mirror Symmetry Lacking Semiconductor TlCd2Te4

2022

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The topological phase transition and exotic quasiparticles in materials have attracted much attention because of their potential in spintronics and mimic of elementary particles. Especially, great research interest has been paid to search for the Weyl fermions in solid-state physics. By using first-principles calculations, we predict that the multinary semiconductor alloy TlCd2Te4 exhibits threefold fermions and nodal-line fermions, which are protected by the S4 improper rotational symmetry. Moreover, owing to the lack of inversion and mirror symmetries, the threefold fermions split into Weyl fermions when the spin-orbit coupling is included. The chiral charge of Weyl points and the Z2 time-reversal topological invariant are investigated. The topological surface states, spin texture, and electron-phonon coupling analysis are presented. Our study demonstrates TlCd2Te4 as a good platform to understand topological phase transitions as well as possible coexistance of topological Weyl semimetal and superconductivity in one single material.

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Section: Methodsmentioning

confidence: 99%

Section: Electronic Structuresmentioning

confidence: 99%

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Threefold Fermions, Weyl Points, and Superconductivity in the Mirror Symmetry Lacking Semiconductor TlCd2Te4

2022

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“…One of the rational ways to develop new functional materials is the search for complex structural analogues of already known compounds with the same properties and to optimize their characteristics by directional alloying [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

New Thallium Tellurides with Rare Earth Elements

Imamaliyeva

2020

kcmf

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Compounds of the Tl4LnTe3 (Ln-Nd, Sm, Tb, Er, Tm) composition were synthesized by the direct interaction of stoichiometric amounts of thallium telluride Tl2Te elementary rare earth elements (REE) and tellurium in evacuated (10-2 Pa) quartz ampoules. The samples obtained were identified by differential thermal and X-ray phase analyses. Based on the data from the heating thermograms, it was shown that these compounds melt with decomposition by peritectic reactions. Analysis of powder diffraction patterns showed that they were completely indexed in a tetragonal lattice of the Tl5Te3 type (space group I4/mcm). Using the Le Bail refinement, the crystal lattice parameters of the synthesized compounds were calculated.It was found that when the thallium atoms located in the centres of the octahedra were substituted by REE atoms, there occurred a sharp decrease in the а parameter and an increase in the с parameter. This was due to the fact that the substitution of thallium atoms with REE cations led to the strengthening of chemical bonds with tellurium atoms. This was accompanied by some distortion of octahedra and an increase in the с parameter. A correlation between the parameters of the crystal lattices and the atomic number of the lanthanide was revealed: during the transition from neodymium to thulium, therewas an almost linear decrease in both parameters of the crystal lattice, which was apparently associated with lanthanide contraction. The obtained new compounds complement the extensive class of ternary compounds - structural analogues of Tl5Te3 and are of interest as potential thermoelectric and magnetic materials. References1. Berger L. I., Prochukhan V. D. Troinye almazopodobnyepoluprovodniki [Ternary diamond-like semiconductors].Moscow: Metallurgiya; 1968. 151 p. (In Russ.)2. Villars P, Prince A. Okamoto H. Handbook ofternary alloy phase diagrams (10 volume set). MaterialsPark, OH: ASM International; 1995. 15000 p.3. Tomashyk V. N. Multinary Alloys Based on III-VSemiconductors. CRC Press; 2018. 262 p. DOI: https://doi.org/10.1201/97804290553484. Babanly M. B., Chulkov E. V., Aliev Z. S. et al. Phasediagrams in materials science of topological insulatorsbased on metal chalkogenides. Russian Journal ofInorganic Chemistry. 2017;62(13): 1703–1729. DOI:https://doi.org/10.1134/S00360236171300345. Imamaliyeva S. Z., Babanly D. M., Tagiev D. B.,Babanly M. B. Physicochemical aspects of developmentof multicomponent chalcogenide phases having theTl5Te3 structure. A Review. Russian Journal of InorganicChemistry. 2018;63(13): 1703–1724 DOI: https://doi.org/10.1134/s00360236181300416. Asadov M. M., Babanly M. B., Kuliev A. A. Phaseequilibria in the system Tl–Te. Izvestiya Akademii NaukSSSR, Neorganicheskie Materialy. 1977;13(8): 1407–1410.7. Okamoto H. Te-Tl (Tellurium-Thallium). Journalof Phase Equilibria. 2001;21(5): 501. 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Multinary Alloys Based on III-V Semiconductors

Cited by 2 publications

References 0 publications

Threefold Fermions, Weyl Points, and Superconductivity in the Mirror Symmetry Lacking Semiconductor TlCd2Te4

Threefold Fermions, Weyl Points, and Superconductivity in the Mirror Symmetry Lacking Semiconductor TlCd2Te4

New Thallium Tellurides with Rare Earth Elements

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