2022
DOI: 10.1038/s41598-022-18439-7
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Temperature induced modulation of resonant Raman scattering in bilayer 2H-MoS2

Abstract: The temperature evolution of the resonant Raman scattering from high-quality bilayer 2H-MoS$$_{2}$$ 2 encapsulated in hexagonal BN flakes is presented. The observed resonant Raman scattering spectrum as initiated by the laser energy of 1.96 eV, close to the A excitonic resonance, shows rich and distinct vibrational features that are otherwise not observed in non-resonant scattering. The appearance of 1st and 2nd ord… Show more

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Cited by 12 publications
(11 citation statements)
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“…Strong resonant Raman scatterings are superimposed over the background of A exciton emission, which is not present for the non-resonant Raman spectra at 78 K (Figure S4c in the Supporting Information) and room-temperature helicity PL (Figure b). Similarly, with the previous reports on ML MoS 2 and WS 2 , the enhanced Raman scattering is due to electron–phonon coupling in the vicinity of A excitonic resonances, which allows us to study the effect of EPC on the depolarization by the evolution of PL helicity with the resonant Raman modes. From the detailed analysis of the background exciton emission and the resonant Raman spectra after subtracting the backgrounds (Figure S4d–i in the Supporting Information), the Raman peaks at 456.0, 405.1, and 384.4 cm –1 can be attributed to B 2g 1 , A 1g , and E 2g 1 zone-center (Γ) vibrations of MoS 2 , respectively, while peaks at 260.6 and 229.6 cm –1 in the lower frequency range are assigned to B 2g 1 -ZA and LA phonons around the K and/or M point of the Brillouin zone, respectively.…”
Section: Resultssupporting
confidence: 64%
“…Strong resonant Raman scatterings are superimposed over the background of A exciton emission, which is not present for the non-resonant Raman spectra at 78 K (Figure S4c in the Supporting Information) and room-temperature helicity PL (Figure b). Similarly, with the previous reports on ML MoS 2 and WS 2 , the enhanced Raman scattering is due to electron–phonon coupling in the vicinity of A excitonic resonances, which allows us to study the effect of EPC on the depolarization by the evolution of PL helicity with the resonant Raman modes. From the detailed analysis of the background exciton emission and the resonant Raman spectra after subtracting the backgrounds (Figure S4d–i in the Supporting Information), the Raman peaks at 456.0, 405.1, and 384.4 cm –1 can be attributed to B 2g 1 , A 1g , and E 2g 1 zone-center (Γ) vibrations of MoS 2 , respectively, while peaks at 260.6 and 229.6 cm –1 in the lower frequency range are assigned to B 2g 1 -ZA and LA phonons around the K and/or M point of the Brillouin zone, respectively.…”
Section: Resultssupporting
confidence: 64%
“…The presence of IR-active modes in the Raman spectra can be related to strain, disorder, or Coulomb interactions [30]. In fact, the IR-active modes are apparent in the RS spectra in several TMDs due to the presence of symmetry breaking, disorder, or resonant conditions of RS excitation [12,22,25,[31][32][33]. However, the observation of both LO and TO modes of the A 2u mode can be related to the ionic bonding in HfS 2 .…”
Section: Discussionmentioning
confidence: 99%
“…Finally, let us address the effect of resonant excitation on the measured RS spectra, shown in figure 5. The resonant excitation may lead to a significant enhancement of the RS intensity in TMD as well as the activation of otherwise inactive modes [25,35]. This offers supplementary information on the coupling of particular phonons to electronic transitions of a specific symmetry [20].…”
Section: Discussionmentioning
confidence: 99%
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“…This reduction in gap suggests the weaker interlayer interaction and vibrational motion of surface modified HTL layer, supporting relative displacement in higher wavelength zones. [30,31] Raman spectra have been taken at 300K using a 532 nm laser source at 2.33 eV excitation energy (Figure S10, Supporting Information). The first-order longitudinal (LO) mode and second-order longitudinal (2LO) of NiO x are represented by the stronger Raman peaks observed at ≈560 and 1095 cm −1 , respectively (Figure S10, Supporting Information).…”
Section: Materials Characterizationsmentioning
confidence: 99%