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Raman Scattering with infrared excitation resonant with MoSe₂ indirect band gap

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arxiv 2208.02505 v1 pith:W5J6Y5GA submitted 2022-08-04 cond-mat.mtrl-sci

Raman Scattering with infrared excitation resonant with MoSe₂ indirect band gap

classification cond-mat.mtrl-sci
keywords modestwo-phononexcitationramanresonancebanddensityindirect
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Resonance Raman scattering, which probes electrons, phonons and their interplay in crystals, is extensively used in two-dimensional materials. Here we investigate Raman modes in MoSe$_2$ at different laser excitation energies from 2.33 eV down to the near infrared 1.16 eV. The Raman spectrum at 1.16 eV excitation energy shows that the intensity of high-order modes is strongly enhanced if compared to the first-order phonon modes intensity due to resonance effects with the MoSe$_2$ indirect band gap. By comparing the experimental results with the two-phonon density of states calculated with density functional theory, we show that the high-order modes originate mostly from two-phonon modes with opposite momenta. In particular, we identify the momenta of the phonon modes that couple strongly with the electrons to produce the resonance process at 1.16 eV, while we verify that at 2.33 eV the two-phonon modes lineshape compares well with the two-phonon density of state calculated over the entire Brillouin Zone. We also show that, by lowering the crystal temperature, we actively suppress the intensity of the resonant two-phonon modes and we interpret this as the result of the increase of the indirect band gap at low temperature that moves our excitation energy out of the resonance condition.

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