Directional transport of centimeter-scale object on anisotropic microcilia surface under water

Yuefeng Wang; Xiaodong Chen; Kang Sun; Ke Li; Feilong Zhang; Bing Dai; Jun Shen; Guoqing Hu; Shutao Wang

doi:10.1007/s40843-018-9302-4

Directional transport of centimeter-scale object on anisotropic microcilia surface under water

Yuefeng Wang, Xiaodong Chen, Kang Sun, Ke Li, Feilong Zhang, Bing Dai, Jun Shen, Guoqing Hu, Shutao Wang^*

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

Natural organisms such as cactus spines or trachea cilia have unique directional transport ability, owing to their anisotropic surface structures or asymmetric motion. However, most artificial interfacial materials are incapable of transporting macroscale object underwater. Herein, we report that anisotropic microcilia arrays, composed of cobalt fine powder and PDMS, can successfully transport the centimeter-scale hydrogel underwater by periodically asymmetric stroke under alternative magnetic field. Reciprocal collective stroke of anisotropic microcilia can generate directional flow, propelling the centimeter-scale hydrogel slice forward. Accompanying computational simulation results are consistent with the directional transport behaviors observed in our experiments. This study provides a clue to design artificial anisotropic interfacial materials with capability of transporting macroscale object at low Reynolds number.

Translated title of the contribution	水下各向异性人造纤毛表面实现厘米尺度的块体输运
Original language	English
Pages (from-to)	236-244
Number of pages	9
Journal	Science China Materials
Volume	62
Issue number	2
DOIs	https://doi.org/10.1007/s40843-018-9302-4
Publication status	Published - 1 Feb 2019
Externally published	Yes

Keywords

anisotropic surface
artificial micro-cilia arrays
macro-object transport

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10.1007/s40843-018-9302-4

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Wang, Y., Chen, X., Sun, K., Li, K., Zhang, F., Dai, B., Shen, J., Hu, G., & Wang, S. (2019). Directional transport of centimeter-scale object on anisotropic microcilia surface under water. Science China Materials, 62(2), 236-244. https://doi.org/10.1007/s40843-018-9302-4

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abstract = "Natural organisms such as cactus spines or trachea cilia have unique directional transport ability, owing to their anisotropic surface structures or asymmetric motion. However, most artificial interfacial materials are incapable of transporting macroscale object underwater. Herein, we report that anisotropic microcilia arrays, composed of cobalt fine powder and PDMS, can successfully transport the centimeter-scale hydrogel underwater by periodically asymmetric stroke under alternative magnetic field. Reciprocal collective stroke of anisotropic microcilia can generate directional flow, propelling the centimeter-scale hydrogel slice forward. Accompanying computational simulation results are consistent with the directional transport behaviors observed in our experiments. This study provides a clue to design artificial anisotropic interfacial materials with capability of transporting macroscale object at low Reynolds number.",

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AU - Wang, Yuefeng

AU - Chen, Xiaodong

AU - Sun, Kang

AU - Li, Ke

AU - Zhang, Feilong

AU - Dai, Bing

AU - Shen, Jun

AU - Hu, Guoqing

AU - Wang, Shutao

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N2 - Natural organisms such as cactus spines or trachea cilia have unique directional transport ability, owing to their anisotropic surface structures or asymmetric motion. However, most artificial interfacial materials are incapable of transporting macroscale object underwater. Herein, we report that anisotropic microcilia arrays, composed of cobalt fine powder and PDMS, can successfully transport the centimeter-scale hydrogel underwater by periodically asymmetric stroke under alternative magnetic field. Reciprocal collective stroke of anisotropic microcilia can generate directional flow, propelling the centimeter-scale hydrogel slice forward. Accompanying computational simulation results are consistent with the directional transport behaviors observed in our experiments. This study provides a clue to design artificial anisotropic interfacial materials with capability of transporting macroscale object at low Reynolds number.

AB - Natural organisms such as cactus spines or trachea cilia have unique directional transport ability, owing to their anisotropic surface structures or asymmetric motion. However, most artificial interfacial materials are incapable of transporting macroscale object underwater. Herein, we report that anisotropic microcilia arrays, composed of cobalt fine powder and PDMS, can successfully transport the centimeter-scale hydrogel underwater by periodically asymmetric stroke under alternative magnetic field. Reciprocal collective stroke of anisotropic microcilia can generate directional flow, propelling the centimeter-scale hydrogel slice forward. Accompanying computational simulation results are consistent with the directional transport behaviors observed in our experiments. This study provides a clue to design artificial anisotropic interfacial materials with capability of transporting macroscale object at low Reynolds number.

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Directional transport of centimeter-scale object on anisotropic microcilia surface under water

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Keywords

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