Pressurized vascular systems for self-healing materials
Pressurized vascular systems for self-healing materials
An emerging strategy for creating self-healing materials relies on embedded vascular networks of microchannels to transport reactive fluids to regions of damage. Here we investigate the use of active pumping for the pressurized delivery of a two-part healing system, allowing a small vascular system to deliver large volumes of healing agent. Different pumping strategies are explored to improve the mixing and subsequent polymerization of healing agents in the damage zone. Significant improvements in the number of healing cycles and in the overall healing efficiency are achieved compared with prior passive schemes that use only capillary forces for the delivery of healing agents. At the same time, the volume of the vascular system required to achieve this superior healing performance is significantly reduced. In the best case, nearly full recovery of fracture toughness is attained throughout 15 cycles of damage and healing, with a vascular network constituting just 0.1 vol% of the specimen.
Bioinspired, Fracture, Microvascular, Self-healing
1020-1028
Hamilton, A.R.
9088cf01-8d7f-45f0-af56-b4784227447c
Sottos, N.R.
a329a43c-958b-46fa-9a2c-cb53cd7e4d12
White, S.R.
bcdc6d47-824d-4014-a8e2-58b48cdc8c99
7 May 2012
Hamilton, A.R.
9088cf01-8d7f-45f0-af56-b4784227447c
Sottos, N.R.
a329a43c-958b-46fa-9a2c-cb53cd7e4d12
White, S.R.
bcdc6d47-824d-4014-a8e2-58b48cdc8c99
Hamilton, A.R., Sottos, N.R. and White, S.R.
(2012)
Pressurized vascular systems for self-healing materials.
Journal of the Royal Society Interface, 9 (70), .
(doi:10.1098/rsif.2011.0508).
Abstract
An emerging strategy for creating self-healing materials relies on embedded vascular networks of microchannels to transport reactive fluids to regions of damage. Here we investigate the use of active pumping for the pressurized delivery of a two-part healing system, allowing a small vascular system to deliver large volumes of healing agent. Different pumping strategies are explored to improve the mixing and subsequent polymerization of healing agents in the damage zone. Significant improvements in the number of healing cycles and in the overall healing efficiency are achieved compared with prior passive schemes that use only capillary forces for the delivery of healing agents. At the same time, the volume of the vascular system required to achieve this superior healing performance is significantly reduced. In the best case, nearly full recovery of fracture toughness is attained throughout 15 cycles of damage and healing, with a vascular network constituting just 0.1 vol% of the specimen.
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More information
Accepted/In Press date: 8 September 2011
e-pub ahead of print date: 22 March 2012
Published date: 7 May 2012
Keywords:
Bioinspired, Fracture, Microvascular, Self-healing
Identifiers
Local EPrints ID: 413355
URI: http://eprints.soton.ac.uk/id/eprint/413355
ISSN: 1742-5689
PURE UUID: 09bf3a84-9869-4f83-b70e-013fc56637ae
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Date deposited: 22 Aug 2017 16:31
Last modified: 16 Mar 2024 04:30
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Contributors
Author:
N.R. Sottos
Author:
S.R. White
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