2018
DOI: 10.1021/jacs.7b09964
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Tellurium: Fast Electrical and Atomic Transport along the Weak Interaction Direction

Abstract: In anisotropic materials, the electrical and atomic transport along the weak interaction direction is usually much slower than that along the chemical bond direction. However, Te, an important semiconductor composed of helical atomic chains, exhibits nearly isotropic electrical transport between intrachain and interchain directions. Using first-principles calculations to study bulk and few-layer Te, we show that this isotropy is related to similar effective masses and potentials for charge carriers along diffe… Show more

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Cited by 110 publications
(77 citation statements)
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“…Tellurium (Te) hosts a unique chiral‐chain structure different from the lattices of the widely studied 2D layered materials [ 59,60 ] ( Figure a.). The helical chains, stacked through a weak interaction, [ 50,61 ] consist of covalently bonded Te atoms and exhibit a three‐fold screw symmetry along the [0001] direction. [ 62 ] The high‐resolution transmission electron microscopy (TEM) results in Figure 1b resolves such characteristic helical‐chain lattice of our solution‐grown 2D Te, which naturally exhibits geometric anisotropy with the long, straight edge always parallel to the [0001] direction [ 45,41,49 ] (Figure 1c).…”
Section: Figurementioning
confidence: 99%
See 1 more Smart Citation
“…Tellurium (Te) hosts a unique chiral‐chain structure different from the lattices of the widely studied 2D layered materials [ 59,60 ] ( Figure a.). The helical chains, stacked through a weak interaction, [ 50,61 ] consist of covalently bonded Te atoms and exhibit a three‐fold screw symmetry along the [0001] direction. [ 62 ] The high‐resolution transmission electron microscopy (TEM) results in Figure 1b resolves such characteristic helical‐chain lattice of our solution‐grown 2D Te, which naturally exhibits geometric anisotropy with the long, straight edge always parallel to the [0001] direction [ 45,41,49 ] (Figure 1c).…”
Section: Figurementioning
confidence: 99%
“…[ 62 ] When the prestrain was applied along the [1¯21¯0] direction, tensile, and compressive strains were induced along the [1¯21¯0] direction in the crest and valley regions, respectively, of the buckled 2D Te. However, the absence of covalent bond along the [1¯21¯0] direction [ 61 ] and larger space (the intrachain between neighboring Te atoms is 0.29 nm, while the interchain distance is 0.35 nm) along this direction makes the external strain to be released without significant bond and bond angle change compared to the [0001] case (see our density functional theory (DFT) calculation results in Table S2, Supporting Information). Moreover, it has been revealed by the previous literature [ 89 ] that the optical activity along [0001] direction is higher than that in the [1¯21¯0] direction in tellurium.…”
Section: Figurementioning
confidence: 99%
“…Most of the components in the reported mixed‐dimensional heterostructures are layered materials with the same planar crystal structures. However, 1D van der Waals elemental materials Se and Te could also exhibit interesting physical properties such as high photoconductivity, high piezoelectricity, thermoelectricity, and nonlinear optical responses . In trigonal Se, the Se atoms are covalently bonded along the c axis into a spiral chain, and these isolated chains could be stacked radially by weak van der Waals interactions to form a hexagonal structure.…”
Section: Introductionmentioning
confidence: 99%
“…6,7 In addition, very recently, structures with few-layers of tellurium were studied as two-dimensional topological materials. 8,9 In fact, it presents topological properties for electronic transport, benetting from the nonsymmorphic screw symmetry, the lonepair electrons and the strong spin-orbit interaction. [10][11][12] For the ground-state chiral tellurium, the band splitting and band inversion were found upon the application of shear strain or pressure [13][14][15] together with the existence of topological Weyl nodes near the Fermi level.…”
Section: Introductionmentioning
confidence: 99%