Anomalous structural phase transition properties in ReSe2 and Au-doped ReSe2

Kao, Yu Chen; Huang, Tsung‐Wei; Lin, Der-Yuh; Huang, Ying; Tiong, K. K.; Lee, Hsin Yi; Lin, Jhih Min; Sheu, Hwo Shuenn; Lin, Chih Ming

doi:10.1063/1.4733985

Cited by 14 publications

(15 citation statements)

References 15 publications

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“…In the previous work, Hou et al [36] have explored the high-pressure structures of ReS 2 up to 51 GPa using synchrotron x-ray diffraction (XRD), they found an indication of the occurrence of a new high-pressure phase at 11 GPa. Kao et al [37] also found a transition in ReSe 2 at the pressure of 10.5 GPa. However, both of them did not resolve the crystal structure of the high-pressure phases.…”

Section: Introductionmentioning

confidence: 86%

Pressure-induced metallization and superconducting phase in ReS 2

Zhou¹,

Zhou²,

Pu³

et al. 2017

npj Quant Mater

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Among the family of transition metal dichalcogenides, ReS 2 occupies a special position, which crystalizes in a unique distorted lowsymmetry structure at ambient conditions. The interlayer interaction in ReS 2 is rather weak, thus its bulk properties are similar to those of monolayer. However, how compression changes its structure and electronic properties is unknown so far. Here using ab initio crystal structure searching techniques, we explore the high-pressure phase transitions of ReS 2 extensively and predict two new high-pressure phases. The ambient pressure phase transforms to a "distorted-1T" structure at very low pressure and then to a tetragonal I4 1 /amd structure at around 90 GPa. The "distorted-1T" structure undergoes a semiconductor-metal transition at around 70 GPa with a band overlap mechanism. Electron-phonon calculations suggest that the I4 1 /amd structure is superconducting and has a critical superconducting temperature of about 2 K at 100 GPa. We further perform high-pressure electrical resistance measurements up to 102 GPa. Our experiments confirm the semiconductor-metal transition and the superconducting phase transition of ReS 2 under high pressure. These experimental results are in good agreement with our theoretical predictions.

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Section: Introductionmentioning

confidence: 86%

Pressure-induced metallization and superconducting phase in ReS 2

Zhou¹,

Zhou²,

Pu³

et al. 2017

npj Quant Mater

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“…3 One of the most direct ways to probe interlayer interaction is by performing highpressure measurements which allow to directly modulate the interlayer distance. In this regard, high-pressure XRD measurements revealed that ReX2 exhibits the largest compressibility amongst all TMDCs, 30,31 and highpressure Raman measurements on ReS2 showed a twofold decreased pressure coefficient of the out-of-plane A1g phonon mode with respect to other TMDCs. 3 spite the fundamental properties of this crystal system being relatively well known at ambient pressure, high-pressure optical measurements would provide highly valuable information in order to evaluate the degree of electronic interlayer coupling in ReX2.…”

Section: Introductionmentioning

confidence: 94%

Pressure dependence of direct optical transitions in ReS2 and ReSe2

et al. 2019

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We present an experimental and theoretical study of the electronic band structure of ReS2 and ReSe2 at high hydrostatic pressures. The experiments are performed by photoreflectance spectroscopy and are analyzed in terms of ab initio calculations within the density functional theory. Experimental pressure coefficients for the two most dominant excitonic transitions are obtained and compared with those predicted by the calculations. We assign the transitions to the Z k-point of the Brillouin zone and other k-points located away from highsymmetry points. The origin of the pressure coefficients of the measured direct transitions is discussed in terms of orbital analysis of the electronic structure and van der Waals interlayer interaction. The anisotropic optical properties are studied at high pressure by means of polarization-resolved photoreflectance measurements. 1. The coordinates of the high-symmetry k-points can be found in the S.I. (Table S1).

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“…[2c] Hall measurement indicated a hole mobility ratio of 1.8 between x ‐ and y ‐direction in few‐layered black phosphors, and infrared spectroscopy study revealed anisotropic in‐plane optical photoconductivity from 2 to 5 µm . Beside black phosphorous, ReSe 2 is another representative anisotropic 2D material, which crystallizes in the low symmetry triclinic system and consists of Re 4 diamond shaped chains in the plane . Consequently, electron transport anisotropy ratio of 3.1 was reported for mechanically exfoliated ReSe 2 nanosheets.…”

mentioning

confidence: 99%

“…Angle‐resolved polarized Raman spectroscopy is a powerful tool to diagnose crystal orientation and anisotropic behavior of materials, which has been previously used in anisotropic 2D nanosheets including ReSe 2 [4c] and black phosphorus . Here we thus performed linearly polarized Raman measurements on our 2D Sb 2 Se 3 nanosheets.…”

mentioning

confidence: 99%

Highly Anisotropic Sb₂Se₃ Nanosheets: Gentle Exfoliation from the Bulk Precursors Possessing 1D Crystal Structure

et al. 2017

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2D materials, particularly those bearing in-plane anisotropic optical and electrical properties such as black phosphorus and ReS , have spurred great research interest very recently as promising building blocks for future electronics. However, current progress is limited to layered compounds that feature atomic arrangement asymmetry within the covalently bonded planes. Herein, a series of highly anisotropic nanosheets (Sb Se , Sb S , Bi S , and Sb (S, Se) ), which are composed of 1D covalently linked ribbons stacked together via van der Waals force, is introduced as a new member to the anisotropic 2D material family. These unique anisotropic nanosheets are successfully fabricated from their polymer-like bulk counterparts through a gentle water freezing-thawing approach. Angle-resolved polarized Raman spectroscopy characterization confirms the strong in-plane asymmetry of Sb Se nanosheets, and photodetection study reveals their high responsivity and anisotropic in-plane transport. This work can enlighten the synthesis and application of new anisotropic 2D nanosheets that can be potentially applied for future electronic and optoelectronic devices.

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Anomalous structural phase transition properties in ReSe2 and Au-doped ReSe2

Cited by 14 publications

References 15 publications

Pressure-induced metallization and superconducting phase in ReS 2

Pressure-induced metallization and superconducting phase in ReS 2

Pressure dependence of direct optical transitions in ReS2 and ReSe2

Highly Anisotropic Sb₂Se₃ Nanosheets: Gentle Exfoliation from the Bulk Precursors Possessing 1D Crystal Structure

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Anomalous structural phase transition properties in ReSe2 and Au-doped ReSe2

Cited by 14 publications

References 15 publications

Pressure-induced metallization and superconducting phase in ReS 2

Pressure-induced metallization and superconducting phase in ReS 2

Pressure dependence of direct optical transitions in ReS2 and ReSe2

Highly Anisotropic Sb2Se3 Nanosheets: Gentle Exfoliation from the Bulk Precursors Possessing 1D Crystal Structure

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Highly Anisotropic Sb₂Se₃ Nanosheets: Gentle Exfoliation from the Bulk Precursors Possessing 1D Crystal Structure