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Ultralow-Frequency Tip-Enhanced Raman Scattering Discovers Nanoscale Radial Breathing Mode on Strained 2D Semiconductors.

Mao-Feng CaoXiao-Hui PengXiao-Jiao ZhaoYi-Fan BaoYuan-Hui XiaoSi-Si WuJun WangYao LuMiao WangXiang WangKai-Qiang LinBin Ren
Published in: Advanced materials (Deerfield Beach, Fla.) (2024)
Collective excitations including plasmons, magnons, and layer-breathing vibration modes emerge at an ultralow frequency (<1 THz) and are crucial for understanding van der Waals materials. Strain at the nanoscale can drastically change the property of van der Waals materials and create localized states like quantum emitters. However, it remains unclear how nanoscale strain changes collective excitations. Herein, ultralow-frequency tip-enhanced Raman spectroscopy (TERS) with sub-10 nm resolution under ambient conditions is developed to explore the localized collective excitation on monolayer semiconductors with nanoscale strains. A new vibrational mode is discovered at around 12 cm -1 (0.36 THz) on monolayer MoSe 2 nanobubbles and it is identified as the radial breathing mode (RBM) of the curved monolayer. The correlation is determined between the RBM frequency and the strain by simultaneously performing deterministic nanoindentation and TERS measurement on monolayer MoSe 2 . The generality of the RBM in nanoscale curved monolayer WSe 2 and bilayer MoSe 2 is demonstrated. Using the RBM frequency, the strain of the monolayer MoSe 2 on the nanoscale can be mapped. Such an ultralow-frequency vibration from curved van der Waals materials provides a new approach to study nanoscale strains and points to more localized collective excitations to be discovered at the nanoscale.
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