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Paper detail

Reflection Phase Shift of One-dimensional Plasmon Polaritons in Carbon Nanotubes

We investigated, both experimentally and theoretically, the reflection phase shift (RPS) of one-dimensional plasmon polaritons. We launched 1D plasmon polaritons in carbon nanotube and probed the plasmon interference pattern using scanning near-field optical microscopy (SNOM) technique, through which a non-zero phase shift was observed. We further developed a theory to understand the nonzero phase shift of 1D polaritons, and found that the RPS can be understood by considering the evanescent field beyond the nanotube end. Interesting, our theory shows a strong dependence of RPS on polaritons wavelength and nanotube diameter, which is in stark contrast to 2D plasmon polaritons in graphene where the RPS is a constant. In short wave region, the RPS of 1D polaritons only depends on a dimensionless variable -- the ratio between polaritons wavelength and nanotube diameter. These results provide fundamental insights into the reflection of polaritons in 1D system, and could facilitate the design of ultrasmall 1D polaritonic devices, such as resonators, interferometers.

preprint2019arXivOpen access
Xingdong LuoCheng HuBosai LyuLiu YangXianliang ZhouAolin DengJi-Hun KangZhiwen Shi
cond-mat.mes-hall
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Xingdong LuoCheng HuBosai LyuLiu YangXianliang ZhouAolin DengJi-Hun KangZhiwen Shi

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