Peptide diffusion and self-assembly in ambient water nanofilm on mica surface

Hai Li; Feng Zhang; Yi Zhang; Ming Ye; Bo Zhou; Yu Zhao Tang; Hai Jun Yang; Mu Yun Xie; Sheng Fu Chen; Jian Hua He; Hai Ping Fang; Jun Hu

doi:10.1021/jp903446g

Peptide diffusion and self-assembly in ambient water nanofilm on mica surface

Hai Li, Feng Zhang, Yi Zhang, Ming Ye, Bo Zhou, Yu Zhao Tang, Hai Jun Yang, Mu Yun Xie, Sheng Fu Chen, Jian Hua He, Hai Ping Fang, Jun Hu

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

38 Scopus citations

Abstract

Ambient water nanofilms confined on solid surfaces usually show properties not seen in bulk and play unique roles in many important processes. Here we report diffusion and self-assembly of peptides in ambient water nanofilms on mica, based on "drying microcontact printing" and ex situ atomic force microscopy imaging. We found that diffusion and self-assembly of several peptides in the water nanofilms on mica resulted in one-dimensional "epitaxial" nanofilaments. The peptide self-assembly process is sensitive to the amount of water on the surface, and different peptides with varied molecular structures show different humidity-dependent behaviors. In addition, some peptides that cannot form nanofilaments on substrates in bulk water can be successfully self-assembled into nanofilaments in the water nanofilm.

Original language	English
Pages (from-to)	8795-8799
Number of pages	5
Journal	Journal of Physical Chemistry B
Volume	113
Issue number	26
DOIs	https://doi.org/10.1021/jp903446g
State	Published - 2 Jul 2009
Externally published	Yes

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title = "Peptide diffusion and self-assembly in ambient water nanofilm on mica surface",

abstract = "Ambient water nanofilms confined on solid surfaces usually show properties not seen in bulk and play unique roles in many important processes. Here we report diffusion and self-assembly of peptides in ambient water nanofilms on mica, based on {"}drying microcontact printing{"} and ex situ atomic force microscopy imaging. We found that diffusion and self-assembly of several peptides in the water nanofilms on mica resulted in one-dimensional {"}epitaxial{"} nanofilaments. The peptide self-assembly process is sensitive to the amount of water on the surface, and different peptides with varied molecular structures show different humidity-dependent behaviors. In addition, some peptides that cannot form nanofilaments on substrates in bulk water can be successfully self-assembled into nanofilaments in the water nanofilm.",

author = "Hai Li and Feng Zhang and Yi Zhang and Ming Ye and Bo Zhou and Tang, {Yu Zhao} and Yang, {Hai Jun} and Xie, {Mu Yun} and Chen, {Sheng Fu} and He, {Jian Hua} and Fang, {Hai Ping} and Jun Hu",

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doi = "10.1021/jp903446g",

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T1 - Peptide diffusion and self-assembly in ambient water nanofilm on mica surface

AU - Li, Hai

AU - Zhang, Feng

AU - Zhang, Yi

AU - Ye, Ming

AU - Zhou, Bo

AU - Tang, Yu Zhao

AU - Yang, Hai Jun

AU - Xie, Mu Yun

AU - Chen, Sheng Fu

AU - He, Jian Hua

AU - Fang, Hai Ping

AU - Hu, Jun

PY - 2009/7/2

Y1 - 2009/7/2

N2 - Ambient water nanofilms confined on solid surfaces usually show properties not seen in bulk and play unique roles in many important processes. Here we report diffusion and self-assembly of peptides in ambient water nanofilms on mica, based on "drying microcontact printing" and ex situ atomic force microscopy imaging. We found that diffusion and self-assembly of several peptides in the water nanofilms on mica resulted in one-dimensional "epitaxial" nanofilaments. The peptide self-assembly process is sensitive to the amount of water on the surface, and different peptides with varied molecular structures show different humidity-dependent behaviors. In addition, some peptides that cannot form nanofilaments on substrates in bulk water can be successfully self-assembled into nanofilaments in the water nanofilm.

AB - Ambient water nanofilms confined on solid surfaces usually show properties not seen in bulk and play unique roles in many important processes. Here we report diffusion and self-assembly of peptides in ambient water nanofilms on mica, based on "drying microcontact printing" and ex situ atomic force microscopy imaging. We found that diffusion and self-assembly of several peptides in the water nanofilms on mica resulted in one-dimensional "epitaxial" nanofilaments. The peptide self-assembly process is sensitive to the amount of water on the surface, and different peptides with varied molecular structures show different humidity-dependent behaviors. In addition, some peptides that cannot form nanofilaments on substrates in bulk water can be successfully self-assembled into nanofilaments in the water nanofilm.

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U2 - 10.1021/jp903446g

DO - 10.1021/jp903446g

M3 - 文章

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VL - 113

SP - 8795

EP - 8799

JO - Journal of Physical Chemistry B

JF - Journal of Physical Chemistry B

IS - 26

ER -

Peptide diffusion and self-assembly in ambient water nanofilm on mica surface

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