Temperature-Activated Layer-Breathing Vibrations in Few-Layer Graphene

Abstract: ABSTRACT:We investigated the low-frequency Raman spectra of freestanding few-layer graphene (FLG) at varying temperatures (400 -900 K) controlled by laser heating. At high temperature, we observed the fundamental Raman mode for the lowest-frequency branch of rigid-plane layer-breathing mode (LBM) vibration. The mode frequency redshifts dramatically from 81 cm -1 for bilayer to 23 cm -1 for 8-layer. The thickness dependence is well described by a simple model of coupled oscillators. Notably, the LBM Raman respo… Show more

“…Its lower frequency (28.8 cm À 1 ) than that of the BLG C 21 and 4LG C 42 suggests a softening of the coupling between layers next to the interface. C 21 þ has a higher frequency than C 21 À because the weakly coupled middle layers vibrate out-of-phase in this case. If this coupling were as strong as in the Bernal-stacked case, Pos(C 21 þ ) would be much higher than Pos(C 21 À ), close to Pos(C 41 ) in 4LG.…”

“…C 21 þ has a higher frequency than C 21 À because the weakly coupled middle layers vibrate out-of-phase in this case. If this coupling were as strong as in the Bernal-stacked case, Pos(C 21 þ ) would be much higher than Pos(C 21 À ), close to Pos(C 41 ) in 4LG. The frequency difference between C 21 À and C 21 þ is referred to as Davydov splitting 35 , which is the frequency difference of two conjugate vibration modes.…”

“…This is 1.2 cm À 1 bigger than that (B1 cm À 1 ) measured in Bernalstacked BLG. In fact, this band can be fitted using two Lorentzians at B28.9 cm À 1 and 30.6 cm À 1 , denoted as C 21 À and C 21 þ , respectively. In t(2 þ 3)LG, besides the two C modes of its 3LG constituent, an additional mode at 30.8 cm À 1 related to its 2LG constituent is present, with a small FWHM B1 cm À 1 .…”

“…Thus, Pos(C 42 )B31 cm À 1 is equal to that of the C mode in 2LG (the latter, however, corresponding to a Raman active mode) 18 . In t(2 þ 2)LG, the displacements of the middle layers are in-phase for C 21 À . Its lower frequency (28.8 cm À 1 ) than that of the BLG C 21 and 4LG C 42 suggests a softening of the coupling between layers next to the interface.…”

“…The Raman spectrum of graphite and MLG consists of two fundamentally different sets of peaks. Those, such as D, G and 2D, present also in SLG, and due to in-plane vibrations 14,16,17 , and others, such as the shear (C) modes 18 and the layer breathing modes [19][20][21] , due to the relative motions of the planes themselves, either perpendicular or parallel to their normal. The G peak corresponds to the high-frequency E 2g phonon at G. The D peak is due to the breathing modes of six-atom rings and requires a defect for its activation 16,[22][23][24] .…”

Resonant Raman spectroscopy of twisted multilayer graphene

“…Its lower frequency (28.8 cm À 1 ) than that of the BLG C 21 and 4LG C 42 suggests a softening of the coupling between layers next to the interface. C 21 þ has a higher frequency than C 21 À because the weakly coupled middle layers vibrate out-of-phase in this case. If this coupling were as strong as in the Bernal-stacked case, Pos(C 21 þ ) would be much higher than Pos(C 21 À ), close to Pos(C 41 ) in 4LG.…”

“…C 21 þ has a higher frequency than C 21 À because the weakly coupled middle layers vibrate out-of-phase in this case. If this coupling were as strong as in the Bernal-stacked case, Pos(C 21 þ ) would be much higher than Pos(C 21 À ), close to Pos(C 41 ) in 4LG. The frequency difference between C 21 À and C 21 þ is referred to as Davydov splitting 35 , which is the frequency difference of two conjugate vibration modes.…”

“…This is 1.2 cm À 1 bigger than that (B1 cm À 1 ) measured in Bernalstacked BLG. In fact, this band can be fitted using two Lorentzians at B28.9 cm À 1 and 30.6 cm À 1 , denoted as C 21 À and C 21 þ , respectively. In t(2 þ 3)LG, besides the two C modes of its 3LG constituent, an additional mode at 30.8 cm À 1 related to its 2LG constituent is present, with a small FWHM B1 cm À 1 .…”

“…Thus, Pos(C 42 )B31 cm À 1 is equal to that of the C mode in 2LG (the latter, however, corresponding to a Raman active mode) 18 . In t(2 þ 2)LG, the displacements of the middle layers are in-phase for C 21 À . Its lower frequency (28.8 cm À 1 ) than that of the BLG C 21 and 4LG C 42 suggests a softening of the coupling between layers next to the interface.…”

“…The Raman spectrum of graphite and MLG consists of two fundamentally different sets of peaks. Those, such as D, G and 2D, present also in SLG, and due to in-plane vibrations 14,16,17 , and others, such as the shear (C) modes 18 and the layer breathing modes [19][20][21] , due to the relative motions of the planes themselves, either perpendicular or parallel to their normal. The G peak corresponds to the high-frequency E 2g phonon at G. The D peak is due to the breathing modes of six-atom rings and requires a defect for its activation 16,[22][23][24] .…”

Resonant Raman spectroscopy of twisted multilayer graphene

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