Jumping on water: Surface tension-dominated jumping of water striders and robotic insects

Je Sung Koh; Eunjin Yang; Gwang Pil Jung; Sun Pill Jung; Jae Hak Son; Sang Im Lee; Piotr G. Jablonski; Robert J. Wood; Ho Young Kim; Kyu Jin Cho

doi:10.1126/science.aab1637

Jumping on water: Surface tension-dominated jumping of water striders and robotic insects

Je Sung Koh
, Eunjin Yang
, Gwang Pil Jung
, Sun Pill Jung
, Jae Hak Son
, Sang Im Lee
, Piotr G. Jablonski
, Robert J. Wood
, Ho Young Kim
, Kyu Jin Cho

Dept. of Mechanical & Automotive Engineering

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

369 Scopus citations

Abstract

Jumping on water is a unique locomotion mode found in semi-aquatic arthropods, such as water striders. To reproduce this feat in a surface tension-dominant jumping robot, we elucidated the hydrodynamics involved and applied them to develop a bio-inspired impulsive mechanism that maximizes momentum transfer to water. We found that water striders rotate the curved tips of their legs inward at a relatively low descending velocity with a force just below that required to break the water surface (144 millinewtons/meter). We built a 68-milligram at-scale jumping robotic insect and verified that it jumps on water with maximum momentum transfer. The results suggest an understanding of the hydrodynamic phenomena used by semi-aquatic arthropods during water jumping and prescribe a method for reproducing these capabilities in artificial systems.

Original language	English
Pages (from-to)	517-521
Number of pages	5
Journal	Science
Volume	349
Issue number	6247
DOIs	https://doi.org/10.1126/science.aab1637
State	Published - 31 Jul 2015

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title = "Jumping on water: Surface tension-dominated jumping of water striders and robotic insects",

abstract = "Jumping on water is a unique locomotion mode found in semi-aquatic arthropods, such as water striders. To reproduce this feat in a surface tension-dominant jumping robot, we elucidated the hydrodynamics involved and applied them to develop a bio-inspired impulsive mechanism that maximizes momentum transfer to water. We found that water striders rotate the curved tips of their legs inward at a relatively low descending velocity with a force just below that required to break the water surface (144 millinewtons/meter). We built a 68-milligram at-scale jumping robotic insect and verified that it jumps on water with maximum momentum transfer. The results suggest an understanding of the hydrodynamic phenomena used by semi-aquatic arthropods during water jumping and prescribe a method for reproducing these capabilities in artificial systems.",

author = "Koh, \{Je Sung\} and Eunjin Yang and Jung, \{Gwang Pil\} and Jung, \{Sun Pill\} and Son, \{Jae Hak\} and Lee, \{Sang Im\} and Jablonski, \{Piotr G.\} and Wood, \{Robert J.\} and Kim, \{Ho Young\} and Cho, \{Kyu Jin\}",

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doi = "10.1126/science.aab1637",

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T1 - Jumping on water

T2 - Surface tension-dominated jumping of water striders and robotic insects

AU - Koh, Je Sung

AU - Yang, Eunjin

AU - Jung, Gwang Pil

AU - Jung, Sun Pill

AU - Son, Jae Hak

AU - Lee, Sang Im

AU - Jablonski, Piotr G.

AU - Wood, Robert J.

AU - Kim, Ho Young

AU - Cho, Kyu Jin

PY - 2015/7/31

Y1 - 2015/7/31

N2 - Jumping on water is a unique locomotion mode found in semi-aquatic arthropods, such as water striders. To reproduce this feat in a surface tension-dominant jumping robot, we elucidated the hydrodynamics involved and applied them to develop a bio-inspired impulsive mechanism that maximizes momentum transfer to water. We found that water striders rotate the curved tips of their legs inward at a relatively low descending velocity with a force just below that required to break the water surface (144 millinewtons/meter). We built a 68-milligram at-scale jumping robotic insect and verified that it jumps on water with maximum momentum transfer. The results suggest an understanding of the hydrodynamic phenomena used by semi-aquatic arthropods during water jumping and prescribe a method for reproducing these capabilities in artificial systems.

AB - Jumping on water is a unique locomotion mode found in semi-aquatic arthropods, such as water striders. To reproduce this feat in a surface tension-dominant jumping robot, we elucidated the hydrodynamics involved and applied them to develop a bio-inspired impulsive mechanism that maximizes momentum transfer to water. We found that water striders rotate the curved tips of their legs inward at a relatively low descending velocity with a force just below that required to break the water surface (144 millinewtons/meter). We built a 68-milligram at-scale jumping robotic insect and verified that it jumps on water with maximum momentum transfer. The results suggest an understanding of the hydrodynamic phenomena used by semi-aquatic arthropods during water jumping and prescribe a method for reproducing these capabilities in artificial systems.

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ER -

Jumping on water: Surface tension-dominated jumping of water striders and robotic insects

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