From an atomic layer to the bulk: Low-temperature atomistic structure and ferroelectric and electronic properties of SnTe films

Kaloni, Thaneshwor P.; Chang, Kai; Miller, Brandon J.; Xue, Qi‐Kun; Chen, Xi; Ji, Shuai‐Hua; Parkin, Stuart S. P.; Barraza‐Lopez, Salvador

doi:10.1103/physrevb.99.134108

Cited by 42 publications

(27 citation statements)

References 88 publications

(99 reference statements)

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“…The conduction band minima (CBM) is found along Y -Γ path and valence band maxima (VBM) is along Γ -X path as shown in Figure 2. The electronic band gap here is in agreement with the previous theoretical result of ~ 0.63 eV, 34 and smaller than the experimental value ~ 0.9 eV. 17 The difference in between the calculated and experimental result is due to the typical problem of Kohn Sham theory in underestimating the band gaps up to 50%.…”

Section: Structural and Electronic Propertiessupporting

confidence: 89%

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Pandit

Haleoot²,

Hamad³

2021

J Mater Sci

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Tin chalcogenides (SnS, SnSe and SnTe) are found to have improved thermoelectric properties upon the reduction of their dimensionality. Here we found the tilted AA + s stacked twodimensional (2D) SnTe bilayer as the most stable phase among several stackings as predicted by the structural optimization and phonon transport properties. The carrier mobility and relaxation time are evaluated using the deformation potential theory -these are found to be relatively high due to the high 2D elastic modulus, low deformation potential constant and moderate effective masses. The SnTe bilayer shows high Seebeck coefficient (> 400 μV/K), high electrical conductivity and ultralow lattice thermal conductivity (< 1.91 Wm -1 K -1 ). High TE figure of merit (ZT) values, as high as 4.61 along zigzag direction, are predicted for SnTe bilayer within the carrier concentration range of the order 10 12 -10 13 cm -2 . These ZT values are much enhanced as compared to the bulk as well as monolayer SnTe and other 2D compounds.

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Section: Structural and Electronic Propertiessupporting

confidence: 89%

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Pandit

Haleoot²,

Hamad³

2021

J Mater Sci

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“…Previous theoretical investigations have evidence that keep the 2D materials away from water and oxygen can enhance the stability of free-standing 2D material significantly. 38,39 Before the sonication, keeping blow the inert gases argon into the Ge NMP solution for a period to remove the oxygen in the solution. After that, the bottle was sealed to cut off oxygen supply during the synthesis of 2D material.…”

Section: Preparation Of 2d Gensmentioning

confidence: 99%

Two-dimensional monoelemental germanene nanosheets: facile preparation and optoelectronic applications

Kang

Xie

et al. 2020

J. Mater. Chem. C

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“…Low-dimensional systems have attracted tremendous attention for their huge potential application in photovoltaics, [1] electronics, [2] and sensors. [3] Especially, driven by the increasing demands of electronics miniaturization, numerous new ferroelectric (FE) nanomaterials have been reported theoretically and experimentally for promising device applications, such as nonvolatile random-access memory devices, [4] fieldeffect transistors (FET), [5] and sensors.…”

Section: Introductionmentioning

confidence: 99%

Quasi‐1D Antiferroelectricity in Centrosymmetric CsTaS₃ Crystal

Bie

Zhou

2022

Advcd Theory and Sims

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1D ferroelectric (FE) materials are expected to be promising low-dimensional materials for nanometer devices, but are rarely reported. The previous experiment discovered that quasi-1D CsTaS 3 crystalizes in centrosymmetric space group, but in which the Ta cations have a strange shift along the c axis from the center of TaS 6 octahedron. Here, the crystal structure, electronic structure, ferroelectric, and piezoelectric properties of CsTaS 3 by using first-principles calculations are studied. It is found that the empty d orbitals of Ta cations induce the distortions of TaS 6 octahedra, which bring the polarity along a given [TaS 3 ] − chain. The adjacent chains are antiferroelectric (AFE) coupling making CsTaS 3 being an AFE material. However, the FE phase of CsTaS 3 is supposed to be accessible since its total energy is only 0.3 meV per formula higher than that of the AFE phase. The polarization of FE CsTaS 3 is estimated to be 16.8 𝝁C cm −2 , which is comparable to those of well-known FE perovskites. The work predicts a quasi-1D AFE material, which would be helpful for subsequent experimental work.

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From an atomic layer to the bulk: Low-temperature atomistic structure and ferroelectric and electronic properties of SnTe films

Cited by 42 publications

References 88 publications

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Two-dimensional monoelemental germanene nanosheets: facile preparation and optoelectronic applications

Quasi‐1D Antiferroelectricity in Centrosymmetric CsTaS₃ Crystal

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From an atomic layer to the bulk: Low-temperature atomistic structure and ferroelectric and electronic properties of SnTe films

Cited by 42 publications

References 88 publications

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Thermal conductivity and enhanced thermoelectric performance of SnTe bilayer

Two-dimensional monoelemental germanene nanosheets: facile preparation and optoelectronic applications

Quasi‐1D Antiferroelectricity in Centrosymmetric CsTaS3 Crystal

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Quasi‐1D Antiferroelectricity in Centrosymmetric CsTaS₃ Crystal