In Situ Investigation on the Nanoscale Capture and Evolution of Aerosols on Nanofibers

Rufan Zhang; Bofei Liu; Ankun Yang; Yangying Zhu; Chong Liu; Guangmin Zhou; Jie Sun; Po Chun Hsu; Wenting Zhao; Dingchang Lin; Yayuan Liu; Allen Pei; Jin Xie; Wei Chen; Jinwei Xu; Yang Jin; Tong Wu; Xuanyi Huang; Yi Cui

doi:10.1021/acs.nanolett.7b04673

In Situ Investigation on the Nanoscale Capture and Evolution of Aerosols on Nanofibers

Rufan Zhang, Bofei Liu, Ankun Yang, Yangying Zhu, Chong Liu, Guangmin Zhou, Jie Sun, Po Chun Hsu, Wenting Zhao, Dingchang Lin, Yayuan Liu, Allen Pei, Jin Xie, Wei Chen, Jinwei Xu, Yang Jin, Tong Wu, Xuanyi Huang, Yi Cui^*

^*Corresponding author for this work

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

72 Citations (Scopus)

Abstract

Aerosol-induced haze problem has become a serious environmental concern. Filtration is widely applied to remove aerosols from gas streams. Despite classical filtration theories, the nanoscale capture and evolution of aerosols is not yet clearly understood. Here we report an in situ investigation on the nanoscale capture and evolution of aerosols on polyimide nanofibers. We discovered different capture and evolution behaviors among three types of aerosols: wetting liquid droplets, nonwetting liquid droplets, and solid particles. The wetting droplets had small contact angles and could move, coalesce, and form axisymmetric conformations on polyimide nanofibers. In contrast, the nonwetting droplets had a large contact angle on polyimide nanofibers and formed nonaxisymmetric conformations. Different from the liquid droplets, the solid particles could not move along the nanofibers and formed dendritic structures. This study provides an important insight for obtaining a deep understanding of the nanoscale capture and evolution of aerosols and benefits future design and development of advanced filters.

Original language	English
Pages (from-to)	1130-1138
Number of pages	9
Journal	Nano Letters
Volume	18
Issue number	2
DOIs	https://doi.org/10.1021/acs.nanolett.7b04673
Publication status	Published - Feb 14 2018
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2018 American Chemical Society.

ASJC Scopus Subject Areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

Keywords

aerosol
capture
filtration
in situ
nanofibers
PM2.5

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10.1021/acs.nanolett.7b04673

Cite this

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title = "In Situ Investigation on the Nanoscale Capture and Evolution of Aerosols on Nanofibers",

abstract = "Aerosol-induced haze problem has become a serious environmental concern. Filtration is widely applied to remove aerosols from gas streams. Despite classical filtration theories, the nanoscale capture and evolution of aerosols is not yet clearly understood. Here we report an in situ investigation on the nanoscale capture and evolution of aerosols on polyimide nanofibers. We discovered different capture and evolution behaviors among three types of aerosols: wetting liquid droplets, nonwetting liquid droplets, and solid particles. The wetting droplets had small contact angles and could move, coalesce, and form axisymmetric conformations on polyimide nanofibers. In contrast, the nonwetting droplets had a large contact angle on polyimide nanofibers and formed nonaxisymmetric conformations. Different from the liquid droplets, the solid particles could not move along the nanofibers and formed dendritic structures. This study provides an important insight for obtaining a deep understanding of the nanoscale capture and evolution of aerosols and benefits future design and development of advanced filters.",

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author = "Rufan Zhang and Bofei Liu and Ankun Yang and Yangying Zhu and Chong Liu and Guangmin Zhou and Jie Sun and Hsu, {Po Chun} and Wenting Zhao and Dingchang Lin and Yayuan Liu and Allen Pei and Jin Xie and Wei Chen and Jinwei Xu and Yang Jin and Tong Wu and Xuanyi Huang and Yi Cui",

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doi = "10.1021/acs.nanolett.7b04673",

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T1 - In Situ Investigation on the Nanoscale Capture and Evolution of Aerosols on Nanofibers

AU - Zhang, Rufan

AU - Liu, Bofei

AU - Yang, Ankun

AU - Zhu, Yangying

AU - Liu, Chong

AU - Zhou, Guangmin

AU - Sun, Jie

AU - Hsu, Po Chun

AU - Zhao, Wenting

AU - Lin, Dingchang

AU - Liu, Yayuan

AU - Pei, Allen

AU - Xie, Jin

AU - Chen, Wei

AU - Xu, Jinwei

AU - Jin, Yang

AU - Wu, Tong

AU - Huang, Xuanyi

AU - Cui, Yi

PY - 2018/2/14

Y1 - 2018/2/14

N2 - Aerosol-induced haze problem has become a serious environmental concern. Filtration is widely applied to remove aerosols from gas streams. Despite classical filtration theories, the nanoscale capture and evolution of aerosols is not yet clearly understood. Here we report an in situ investigation on the nanoscale capture and evolution of aerosols on polyimide nanofibers. We discovered different capture and evolution behaviors among three types of aerosols: wetting liquid droplets, nonwetting liquid droplets, and solid particles. The wetting droplets had small contact angles and could move, coalesce, and form axisymmetric conformations on polyimide nanofibers. In contrast, the nonwetting droplets had a large contact angle on polyimide nanofibers and formed nonaxisymmetric conformations. Different from the liquid droplets, the solid particles could not move along the nanofibers and formed dendritic structures. This study provides an important insight for obtaining a deep understanding of the nanoscale capture and evolution of aerosols and benefits future design and development of advanced filters.

AB - Aerosol-induced haze problem has become a serious environmental concern. Filtration is widely applied to remove aerosols from gas streams. Despite classical filtration theories, the nanoscale capture and evolution of aerosols is not yet clearly understood. Here we report an in situ investigation on the nanoscale capture and evolution of aerosols on polyimide nanofibers. We discovered different capture and evolution behaviors among three types of aerosols: wetting liquid droplets, nonwetting liquid droplets, and solid particles. The wetting droplets had small contact angles and could move, coalesce, and form axisymmetric conformations on polyimide nanofibers. In contrast, the nonwetting droplets had a large contact angle on polyimide nanofibers and formed nonaxisymmetric conformations. Different from the liquid droplets, the solid particles could not move along the nanofibers and formed dendritic structures. This study provides an important insight for obtaining a deep understanding of the nanoscale capture and evolution of aerosols and benefits future design and development of advanced filters.

KW - aerosol

KW - capture

KW - filtration

KW - in situ

KW - nanofibers

KW - PM2.5

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In Situ Investigation on the Nanoscale Capture and Evolution of Aerosols on Nanofibers

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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