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Controlling three-dimensional ice template via two-dimensional surface wetting

Directional freezing (DF) is a fast, scalable, and environmental friendly technique for fabricating monoliths with long-range oriented pores, which can be applied toward a wide variety of materials. However, the pore size is typically larger than 20 μm and cannot be spatially controlled, which preve...

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Main Authors: Yang, M., Wu, J., Bai, H., Xie, T., Zhao, Q., Wong, T. W.
Format: Article
Published: John Wiley and Sons Inc. 2016
Subjects:
Q Science (General)
Online Access:http://eprints.utm.my/id/eprint/71848/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-84994067213&doi=10.1002%2faic.15509&partnerID=40&md5=749c71c8573cfa3369b32e8b10d38fb4
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spelling my.utm.718482017-11-16T05:36:26Z http://eprints.utm.my/id/eprint/71848/ Controlling three-dimensional ice template via two-dimensional surface wetting Yang, M. Wu, J. Bai, H. Xie, T. Zhao, Q. Wong, T. W. Q Science (General) Directional freezing (DF) is a fast, scalable, and environmental friendly technique for fabricating monoliths with long-range oriented pores, which can be applied toward a wide variety of materials. However, the pore size is typically larger than 20 μm and cannot be spatially controlled, which prevent the technique from being used more widely. In this work, effect of wettability of the freezing substrate on the pore size of monolithic polyethylene glycol cryogels is studied. Smaller pores can be generated via more hydrophilic substrates, and tubular pores smaller 5 μm can be created using a poly(vinyl alcohol) coated copper substrate. A numerical fitting between water contact angle of the substrates and pore size is then obtained. Moreover, pore size can be locally varied duplicating wetting patterns of the substrates. The concept of using two dimensional patterns to build monoliths with three dimensional microstructures can probably be extended to other material systems. DF is an effecient and scalable processing method for fabricating materials with long-range oriented pores. However, the smallest pore feature size reported is around 20 µm, which is in many cases too large for application such as separation and catalysis. We show here, with exemplary cryogels, that both spatial control and feature size reduction (by one order of magnitude) can be realized in DF by controlling the wettability of the ice growth substrate. John Wiley and Sons Inc. 2016 Article PeerReviewed Yang, M. and Wu, J. and Bai, H. and Xie, T. and Zhao, Q. and Wong, T. W. (2016) Controlling three-dimensional ice template via two-dimensional surface wetting. AIChE Journal, 62 (12). pp. 4186-4192. ISSN 0001-1541 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84994067213&doi=10.1002%2faic.15509&partnerID=40&md5=749c71c8573cfa3369b32e8b10d38fb4
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic Q Science (General)
spellingShingle Q Science (General)
Yang, M.
Wu, J.
Bai, H.
Xie, T.
Zhao, Q.
Wong, T. W.
Controlling three-dimensional ice template via two-dimensional surface wetting
description Directional freezing (DF) is a fast, scalable, and environmental friendly technique for fabricating monoliths with long-range oriented pores, which can be applied toward a wide variety of materials. However, the pore size is typically larger than 20 μm and cannot be spatially controlled, which prevent the technique from being used more widely. In this work, effect of wettability of the freezing substrate on the pore size of monolithic polyethylene glycol cryogels is studied. Smaller pores can be generated via more hydrophilic substrates, and tubular pores smaller 5 μm can be created using a poly(vinyl alcohol) coated copper substrate. A numerical fitting between water contact angle of the substrates and pore size is then obtained. Moreover, pore size can be locally varied duplicating wetting patterns of the substrates. The concept of using two dimensional patterns to build monoliths with three dimensional microstructures can probably be extended to other material systems. DF is an effecient and scalable processing method for fabricating materials with long-range oriented pores. However, the smallest pore feature size reported is around 20 µm, which is in many cases too large for application such as separation and catalysis. We show here, with exemplary cryogels, that both spatial control and feature size reduction (by one order of magnitude) can be realized in DF by controlling the wettability of the ice growth substrate.
format Article
author Yang, M.
Wu, J.
Bai, H.
Xie, T.
Zhao, Q.
Wong, T. W.
author_facet Yang, M.
Wu, J.
Bai, H.
Xie, T.
Zhao, Q.
Wong, T. W.
author_sort Yang, M.
title Controlling three-dimensional ice template via two-dimensional surface wetting
title_short Controlling three-dimensional ice template via two-dimensional surface wetting
title_full Controlling three-dimensional ice template via two-dimensional surface wetting
title_fullStr Controlling three-dimensional ice template via two-dimensional surface wetting
title_full_unstemmed Controlling three-dimensional ice template via two-dimensional surface wetting
title_sort controlling three-dimensional ice template via two-dimensional surface wetting
publisher John Wiley and Sons Inc.
publishDate 2016
url http://eprints.utm.my/id/eprint/71848/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-84994067213&doi=10.1002%2faic.15509&partnerID=40&md5=749c71c8573cfa3369b32e8b10d38fb4
_version_ 1643656295917551616
score 13.159267

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