Raman anomalies as signatures of pressure induced electronic topological and structural transitions in black phosphorus: Experiments and theory

Gupta, Sanjay; Singh, Anjali; Pal, Koushik; Chakraborti, Biswanath; Muthu, D. V. S.; Waghmare, Umesh V.; Sood, Anil K.

doi:10.1103/physrevb.96.094104

Cited by 38 publications

(44 citation statements)

References 58 publications

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“…However at this moment it is difficult to confirm it without any detailed theoretical study. Similar anomalies have been observed earlier during ETT in other systems [36,39,40,42,43,45,46] and are probably a precursor to semiconductor to metallic transition. It may be noted that the triclinic phase, which is known to be metallic also shows a slope change in Eulerian strain at 17GPa, which matches well with the end of plateau region in c/a-ratio of the hexagonal phase.…”

Section: Resultssupporting

confidence: 86%

“…We clearly see the electron phonon coupling changes with pressure, showing a broad minimum reflecting similar behaviour of FWHM. Similar dip in electron phonon coupling was observed in Black Phosphorus and attributed to ETT [46]. Pressure dependent resistivity measurements by Zhao et al [11] show a step like characteristic in the pressure range about 12-20 GPa similar to the c/a-ratio of the hexagonal phase.…”

Section: Resultssupporting

confidence: 69%

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High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies

Saha

Ghosh

Mazumder

et al. 2020

Mater. Res. Express

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Detailed high pressure Resonance Raman (RR) Spectroscopy and x-ray diffraction (XRD) studies are carried out on 3-4 layered MoSe 2 obtained by liquid exfoliation. Analysis of ambient XRD pattern and RR spectra indicate the presence of a triclinic phase along with its parent hexagonal phase. Slope change in the linear behavior of reduced pressure (H) with respect to Eulerian strain ( f E ) is observed at about 13 GPa in hexagonal phase and at about 17 GPa for the triclinic phase. High pressure Raman measurements using two different pressure transmitting media (PTM) show three linear pressure regions, separated by pressure values around which anomalies in the structure are observed. A broad minimum in the FWHM values of E g 2 1 mode at about 10-12 GPa indicate to an electron-phonon coupling. Above 33 GPa the sample completely gets converted to the triclinic structure, which indicates the importance of strain in structural as well as electronic properties of two dimensional materials.

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Section: Resultssupporting

confidence: 86%

Section: Resultssupporting

confidence: 69%

High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies

Saha

Ghosh

Mazumder

et al. 2020

Mater. Res. Express

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“…The pressure-induced electronic topological and structural transitions have been investigated for black phosphorus experimentally and theoretically. [33] The accurate HSE calculations demonstrated the occurrence of band inversion at 1.2 GPa. The strong topological index 0 = 0 for P < 1.2 GPa and 0 = 1 for P ≥ 1.2 GPa are observed, confirming the transition of the topological insulator phase at above 1.2 GPa.…”

Section: Tuning Of Structurementioning

confidence: 91%

“…The strong topological index 0 = 0 for P < 1.2 GPa and 0 = 1 for P ≥ 1.2 GPa are observed, confirming the transition of the topological insulator phase at above 1.2 GPa. [33] Furthermore, the crystal structures' evolutions of phosphorus are demonstrated under different pressures ( Figure 4g). [32] Under ambient pressure, red phosphorus was stable with triclinic structure (P-I), whereas BP (Cmca) nearly degenerated.…”

Section: Tuning Of Structurementioning

confidence: 99%

“…[11][12][13] Pressure, being an important thermodynamic variable, could provide a powerful method to tune the atomic, electronic, and crystal structures of 2D materials without introducing damages and impurities. [14][15][16] As an example, the pressure-induced dramatic changes in electronic structures and structural phase transitions of transition metal dichalcogenides (TMDs), [17][18][19][20] boron nitride (BN), [21][22][23][24][25][26] MXene, [27][28][29] and black phosphorene (BP) [30][31][32][33][34] have been reported. [15,[17][18][19][20][35][36][37] Compared with their bulk counterparts, 2D TMDs exhibit thickness-dependent phase transitions (from 2H c to 2H a ) under high pressure, and thinner films are more sensitive to pressure in terms of Raman vibration modes.…”

Section: Introductionmentioning

confidence: 99%

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2D Materials and Heterostructures at Extreme Pressure

et al. 2020

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2D materials possess wide-tuning properties ranging from semiconducting and metallization to superconducting, etc., which are determined by their structure, empowering them to be appealing in optoelectronic and photovoltaic applications. Pressure is an effective and clean tool that allows modifications of the electronic structure, crystal structure, morphologies, and compositions of 2D materials through van der Waals (vdW) interaction engineering. This enables an insightful understanding of the variable vdW interaction induced structural changes, structure-property relations as well as contributes to the versatile implications of 2D materials. Here, the recent progress of high-pressure research toward 2D materials and heterostructures, involving graphene, boron nitride, transition metal dichalcogenides, 2D perovskites, black phosphorene, MXene, and covalent-organic frameworks, using diamond anvil cell is summarized. A detailed analysis of pressurized structure, phonon dynamics, superconducting, metallization, doping together with optical property is performed. Further, the pressure-induced optimized properties and potential applications as well as the vision of engineering the vdW interactions in heterostructures are highlighted. Finally, conclusions and outlook are presented on the way forward.

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Vibrational Properties of Pristine and Lithium‐Intercalated Black Phosphorous under High‐Pressure

et al. 2021

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Structural evolution of Li‐intercalated and pristine black phosphorous (BP) under high‐pressure (up to ≈8 GPa) is studied using in situ Raman spectroscopy. Even though both materials show a monotonic blueshift of the out‐of‐plane vibrational mode (A1g) with pressure, Li‐intercalated BP do not show a blueshift until a threshold pressure (2.4 GPa) is reached to compensate the structural expansion caused by intercalation. However, the in‐plane modes (B2g and A2g) in each sample respond differently. In the mid‐pressure region, they both show redshifts which in Li‐intercalated BP is also followed by abrupt blueshifts. Such behavior indicates pressure‐induced structural reorganizations inside the material. Computational modeling reveals the existence of a process of P─P bond breaking and reforming in the system due to the redistribution of intercalated Li atoms under pressure. This work shows the significance of combined effect of pressure and intercalation on structural changes in the search for new phases of BP and other two‐dimensional (2D) materials.

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Raman anomalies as signatures of pressure induced electronic topological and structural transitions in black phosphorus: Experiments and theory

Cited by 38 publications

References 58 publications

High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies

High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies

2D Materials and Heterostructures at Extreme Pressure

Vibrational Properties of Pristine and Lithium‐Intercalated Black Phosphorous under High‐Pressure

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Raman anomalies as signatures of pressure induced electronic topological and structural transitions in black phosphorus: Experiments and theory

Cited by 38 publications

References 58 publications

High pressure anomalies in exfoliated MoSe2: resonance Raman and x-ray diffraction studies

High pressure anomalies in exfoliated MoSe2: resonance Raman and x-ray diffraction studies

2D Materials and Heterostructures at Extreme Pressure

Vibrational Properties of Pristine and Lithium‐Intercalated Black Phosphorous under High‐Pressure

Contact Info

Product

Resources

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High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies

High pressure anomalies in exfoliated MoSe₂: resonance Raman and x-ray diffraction studies