Raman Optical Activity of 1T-TaS<sub>2</sub>

Lacinska, Ewa; Furman, Magdalena; Binder, Johannes; Lutsyk, Iaroslav; Kowalczyk, P.J.; Stępniewski, R.; Wysmołek, A.

doi:10.1021/acs.nanolett.1c04990

Cited by 19 publications

(12 citation statements)

References 46 publications

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“…The out-of-plane A 1g Raman modes for the σ+σ+ and σ−σ− configurations are almost the same, whereas the intensities of in-plane E g modes differ remarkably for the σ+σ− and σ−σ+ configurations, indicating that the chiral Raman response may correspond to an in-plane chiral structure. Similar experimental results of chiral Raman response in 1T-TaS 2 have been reported recently, which were well explained by Raman tensor analysis, either by introducing an antisymmetric Raman tensor or including complex Raman tensor elements 28 , 29 .…”

Section: Resultssupporting

confidence: 88%

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

et al. 2023

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The chiral charge density wave is a many-body collective phenomenon in condensed matter that may play a role in unconventional superconductivity and topological physics. Two-dimensional chiral charge density waves provide the building blocks for the fabrication of various stacking structures and chiral homostructures, in which physical properties such as chiral currents and the anomalous Hall effect may emerge. Here, we demonstrate the phase manipulation of two-dimensional chiral charge density waves and the design of in-plane chiral homostructures in 1T-TaS2. We use chiral Raman spectroscopy to directly monitor the chirality switching of the charge density wave—revealing a temperature-mediated reversible chirality switching. We find that interlayer stacking favours homochirality configurations, which is confirmed by first-principles calculations. By exploiting the interlayer chirality-locking effect, we realise in-plane chiral homostructures in 1T-TaS2. Our results provide a versatile way to manipulate chiral collective phases by interlayer coupling in layered van der Waals semiconductors.

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Section: Resultssupporting

confidence: 88%

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

et al. 2023

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“…Two linear polarizers were set parallel to each otherone in the incoming laser excitation path and the other in the spectrometer detection pathand a half-wave plate was mounted directly in front of the latter polarizer. Rotating the half-wave plate by θ/2 allowed for the detection of Raman scattered light that was effectively rotated by θ with respect to the polarization vector of the incident laser light . For the space group P 6 3 / mmc and specific Wyckoff positions occupied in the Fe 0.23 NbSe 2 crystal structure, the symmetry-adapted phonon modes (SAMs) expected at the zone-center Γ SL point are: Γ acoustic = A 2u + E 1u and Γ optical = 4A 1g + A 1u + 2A 2g + 5A 2u + 5B 1g + 2B 1u + B 2g + 5B 2u + 5E 1g + 7E 1u + 7E 2g + 6E 2u . − Based on the optical phonons present, the expected Raman-active modes are 4A 1g + 5E 1g + 7E 2g . − As in the unpolarized Raman experiment, the backscattering measurement geometry along the ZZ direction precludes the detection of the E 1g modes for materials with this space group symmetry …”

Section: Resultsmentioning

confidence: 99%

Bridging Structure, Magnetism, and Disorder in Iron-Intercalated Niobium Diselenide, Fe_xNbSe₂, below x = 0.25

Erodici,

Mai,

Xie

et al. 2023

J. Phys. Chem. C

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Transition-metal dichalcogenides (TMDs) intercalated with magnetic ions serve as a promising materials platform for developing next-generation, spin-based electronic technologies. In these materials, one can access a rich magnetic phase space depending on the choice of intercalant, host lattice, and relative stoichiometry. The distribution of these intercalant ions across given crystals, however, is less well definedparticularly away from ideal packing stoichiometriesand a convenient probe to assess potential longer-range ordering of intercalants is lacking. Here, we demonstrate that confocal Raman spectroscopy is a powerful tool for mapping the onset of intercalant superlattice formation in Fe-intercalated NbSe2 (Fe x NbSe2) for 0.14 ≤ x < 0.25. We use single-crystal X-ray diffraction to confirm the presence of longer-range intercalant superstructure and employ polarization-, temperature-, and magnetic field-dependent Raman measurements to examine both the symmetry of emergent phonon modes in the intercalated material and potential magnetoelastic coupling. Magnetometry measurements further indicate a correlation between the onset of magnetic ordering and the relative degree of intercalant superlattice formation. These results show Raman spectroscopy to be an expedient, local probe for mapping intercalant ordering in this class of magnetic materials.

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“…In bulk 1T-TaS 2 , (purple spectrum), the intense peaks in the range of 70 to 130 cm −1 , as well as the low-intensity peaks in the range of 225 to 400 cm −1 range, are attributed to the zone-folded acoustic and optical phonons. [50][51][52][53] These phonon branches appear because of Brillouin zone reconstruction in the C-CDW phase and disappear during the C-CDW-NC-CDW phase transition. [51] At 93 K, the bulk crystal and the fillers are all in the C-CDW phase.…”

Section: Resultsmentioning

confidence: 99%

“…Raman spectroscopy is a standard technique for monitoring CDW phase transition owing to its sensitivity to the crystal lattice distortions, reconstruction and phonon folding due to CDW periodicity, and the loss of translation symmetry in the IC-CDW phase. [49][50][51][52][53] The Raman spectra were accumulated in the conventional backscattering configuration at T ≈ 93 K. The Raman laser spot size was ≈1 µm. Experiments were conducted with the minimum laser power to avoid any laser-induced heating effects.…”

Section: Resultsmentioning

confidence: 99%

Quantum Composites with Charge‐Density‐Wave Fillers

et al. 2023

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A unique class of advanced materials—quantum composites based on polymers with fillers composed of a van der Waals quantum material that reveals multiple charge‐density‐wave quantum condensate phases—is demonstrated. Materials that exhibit quantum phenomena are typically crystalline, pure, and have few defects because disorder destroys the coherence of the electrons and phonons, leading to collapse of the quantum states. The macroscopic charge‐density‐wave phases of filler particles after multiple composite processing steps are successfully preserved in this work. The prepared composites display strong charge‐density‐wave phenomena even above room temperature. The dielectric constant experiences more than two orders of magnitude enhancement while the material maintains its electrically insulating properties, opening a venue for advanced applications in energy storage and electronics. The results present a conceptually different approach for engineering the properties of materials, extending the application domain for van der Waals materials.

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Raman Optical Activity of 1T-TaS₂

Cited by 19 publications

References 46 publications

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

Bridging Structure, Magnetism, and Disorder in Iron-Intercalated Niobium Diselenide, Fe_xNbSe₂, below x = 0.25

Quantum Composites with Charge‐Density‐Wave Fillers

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Raman Optical Activity of 1T-TaS2

Cited by 19 publications

References 46 publications

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

Spectroscopic visualization and phase manipulation of chiral charge density waves in 1T-TaS2

Bridging Structure, Magnetism, and Disorder in Iron-Intercalated Niobium Diselenide, FexNbSe2, below x = 0.25

Quantum Composites with Charge‐Density‐Wave Fillers

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Product

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Raman Optical Activity of 1T-TaS₂

Bridging Structure, Magnetism, and Disorder in Iron-Intercalated Niobium Diselenide, Fe_xNbSe₂, below x = 0.25