拉曼光谱
材料科学
碳纳米管
兴奋剂
基质(水族馆)
纳米管
金属
石英
放松(心理学)
压力(语言学)
变形(气象学)
化学物理
纳米技术
密度泛函理论
凝聚态物理
分子物理学
声子
碳纳米管的光学性质
复合材料
碳纤维
分子振动
电子结构
粘附
作者
Authors: Vladimir Pimonov,Eira Anais Zamudio Medina,Huy Tran,Saïd Tahir,Antonin Louiset,Hanako Okuno,Chris Ewels,Camille Latouche,Eric Anglaret,Vincent Jourdain
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-02-25
标识
DOI:10.1021/acsnano.5c20366
摘要
Single-walled carbon nanotubes (SWCNTs) grown on single-crystal quartz exhibit complex Raman features that reflect interactions between the nanotube, substrate, and environment. Here, we combine Raman spectroscopy and DFT calculations to study individual metallic SWCNTs on quartz. As often observed but previously unexplained, the G-band displays four components rather than one or two, with both its shape and position varying along the nanotube length. Our analysis shows that these variations arise from a combination of chemical doping and axial compression, which are strongly correlated. The gradual upshift of the G- and D-bands from the nanotube ends toward the center is primarily due to axial compression (up to ∼1%) that develops upon cooling and cannot relax because of strong substrate adhesion. This adhesion gradually weakens under ambient conditions, allowing partial relaxation of axial stress from the ends, or can be partially suppressed by a strain-releasing treatment. DFT calculations reveal that the G-band splitting originates from strong SWCNT-quartz interactions that induce radial deformation and activate localized, low-symmetry C-C stretching modes: two predominantly circumferential and two predominantly axial. The evolution of the G-band and RBM in metallic SWCNTs reveals a substrate-induced increase in p-type doping originating from a reduction in the SWCNT work function due to quartz interaction, further enhanced by axial strain. Together, these findings elucidate the intertwined effects of adhesion, strain, and doping in determining the Raman response of quartz-grown SWCNTs, highlighting the importance of substrate effects when interpreting Raman data or integrating horizontally aligned SWCNTs into electronic devices.
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