Origin and tuning of surface optic and long wavelength phonons in biomimetic GaAs nanotip arrays

Yi Fan Huang; Surojit Chattopadhyay; Hsu Cheng Hsu; Chien Ting Wu; Kuei Hsien Chen; Li Chyong Chen

doi:10.1364/OME.1.000535

Origin and tuning of surface optic and long wavelength phonons in biomimetic GaAs nanotip arrays

Yi Fan Huang, Surojit Chattopadhyay^*, Hsu Cheng Hsu, Chien Ting Wu, Kuei Hsien Chen, Li Chyong Chen

^*Corresponding author for this work

Institute of Biophotonics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Nano-texturization provides sensitive routes for selection of preferred phonon modes. Biomimetic gallium arsenide (GaAs) nano-tips, with a pencil-like structure, prepared by an electron cyclotron resonance plasma etching of planar GaAs wafer demonstrates tunable strength of the surface optic (SO), and long wavelength transverse optic and longitudinal optic phonon modes. These modes can be tuned as a function of the length (L) of the nano-tips enabling phonon engineering. Invalidation of symmetry rules due to nano-texturization results in the excitation of a SO mode that can also be tuned, in strength and position, with L. Red shift of this mode with a change in the dielectric constant of the medium (air to aniline) confirms the SO nature. The theoretically estimated length scales indicate that the diameter modulated apexes of the nano-tips, whose length (L') increases consistently with L, could be responsible in transferring the required momentum to the SO phonons.

Original language	English
Pages (from-to)	535-542
Number of pages	8
Journal	Optical Materials Express
Volume	1
Issue number	4
DOIs	https://doi.org/10.1364/OME.1.000535
State	Published - 1 Aug 2011

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title = "Origin and tuning of surface optic and long wavelength phonons in biomimetic GaAs nanotip arrays",

abstract = "Nano-texturization provides sensitive routes for selection of preferred phonon modes. Biomimetic gallium arsenide (GaAs) nano-tips, with a pencil-like structure, prepared by an electron cyclotron resonance plasma etching of planar GaAs wafer demonstrates tunable strength of the surface optic (SO), and long wavelength transverse optic and longitudinal optic phonon modes. These modes can be tuned as a function of the length (L) of the nano-tips enabling phonon engineering. Invalidation of symmetry rules due to nano-texturization results in the excitation of a SO mode that can also be tuned, in strength and position, with L. Red shift of this mode with a change in the dielectric constant of the medium (air to aniline) confirms the SO nature. The theoretically estimated length scales indicate that the diameter modulated apexes of the nano-tips, whose length (L') increases consistently with L, could be responsible in transferring the required momentum to the SO phonons.",

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AU - Huang, Yi Fan

AU - Chattopadhyay, Surojit

AU - Hsu, Hsu Cheng

AU - Wu, Chien Ting

AU - Chen, Kuei Hsien

AU - Chen, Li Chyong

PY - 2011/8/1

Y1 - 2011/8/1

N2 - Nano-texturization provides sensitive routes for selection of preferred phonon modes. Biomimetic gallium arsenide (GaAs) nano-tips, with a pencil-like structure, prepared by an electron cyclotron resonance plasma etching of planar GaAs wafer demonstrates tunable strength of the surface optic (SO), and long wavelength transverse optic and longitudinal optic phonon modes. These modes can be tuned as a function of the length (L) of the nano-tips enabling phonon engineering. Invalidation of symmetry rules due to nano-texturization results in the excitation of a SO mode that can also be tuned, in strength and position, with L. Red shift of this mode with a change in the dielectric constant of the medium (air to aniline) confirms the SO nature. The theoretically estimated length scales indicate that the diameter modulated apexes of the nano-tips, whose length (L') increases consistently with L, could be responsible in transferring the required momentum to the SO phonons.

AB - Nano-texturization provides sensitive routes for selection of preferred phonon modes. Biomimetic gallium arsenide (GaAs) nano-tips, with a pencil-like structure, prepared by an electron cyclotron resonance plasma etching of planar GaAs wafer demonstrates tunable strength of the surface optic (SO), and long wavelength transverse optic and longitudinal optic phonon modes. These modes can be tuned as a function of the length (L) of the nano-tips enabling phonon engineering. Invalidation of symmetry rules due to nano-texturization results in the excitation of a SO mode that can also be tuned, in strength and position, with L. Red shift of this mode with a change in the dielectric constant of the medium (air to aniline) confirms the SO nature. The theoretically estimated length scales indicate that the diameter modulated apexes of the nano-tips, whose length (L') increases consistently with L, could be responsible in transferring the required momentum to the SO phonons.

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Origin and tuning of surface optic and long wavelength phonons in biomimetic GaAs nanotip arrays

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