Photopatterned microswimmers with programmable motion without external stimuli

Yeongjae Choi; Cheolheon Park; Amos C. Lee; Junghyun Bae; Hyeli Kim; Hansol Choi; Seo woo Song; Yunjin Jeong; Jaewon Choi; Howon Lee; Sunghoon Kwon; Wook Park

doi:10.1038/s41467-021-24996-8

Photopatterned microswimmers with programmable motion without external stimuli

Yeongjae Choi^*
, Cheolheon Park
, Amos C. Lee
, Junghyun Bae
, Hyeli Kim
, Hansol Choi
, Seo woo Song
, Yunjin Jeong
, Jaewon Choi
, Howon Lee
, Sunghoon Kwon^*
, Wook Park^*

^*Corresponding author for this work

Division of Electronic Engineering

Seoul National University
Harvard University
Kyung Hee University

Research output: Contribution to journal › Journal article › peer-review

50 Scopus citations

Abstract

We introduce highly programmable microscale swimmers driven by the Marangoni effect (Marangoni microswimmers) that can self-propel on the surface of water. Previous studies on Marangoni swimmers have shown the advantage of self-propulsion without external energy source or mechanical systems, by taking advantage of direct conversion from power source materials to mechanical energy. However, current developments on Marangoni microswimmers have limitations in their fabrication, thereby hindering their programmability and precise mass production. By introducing a photopatterning method, we generated Marangoni microswimmers with multiple functional parts with distinct material properties in high throughput. Furthermore, various motions such as time-dependent direction change and disassembly of swimmers without external stimuli are programmed into the Marangoni microswimmers.

Original language	English
Article number	4724
Journal	Nature Communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-24996-8
State	Published - 2021.12.1

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title = "Photopatterned microswimmers with programmable motion without external stimuli",

abstract = "We introduce highly programmable microscale swimmers driven by the Marangoni effect (Marangoni microswimmers) that can self-propel on the surface of water. Previous studies on Marangoni swimmers have shown the advantage of self-propulsion without external energy source or mechanical systems, by taking advantage of direct conversion from power source materials to mechanical energy. However, current developments on Marangoni microswimmers have limitations in their fabrication, thereby hindering their programmability and precise mass production. By introducing a photopatterning method, we generated Marangoni microswimmers with multiple functional parts with distinct material properties in high throughput. Furthermore, various motions such as time-dependent direction change and disassembly of swimmers without external stimuli are programmed into the Marangoni microswimmers.",

author = "Yeongjae Choi and Cheolheon Park and Lee, \{Amos C.\} and Junghyun Bae and Hyeli Kim and Hansol Choi and Song, \{Seo woo\} and Yunjin Jeong and Jaewon Choi and Howon Lee and Sunghoon Kwon and Wook Park",

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doi = "10.1038/s41467-021-24996-8",

language = "English",

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TY - JOUR

T1 - Photopatterned microswimmers with programmable motion without external stimuli

AU - Choi, Yeongjae

AU - Park, Cheolheon

AU - Lee, Amos C.

AU - Bae, Junghyun

AU - Kim, Hyeli

AU - Choi, Hansol

AU - Song, Seo woo

AU - Jeong, Yunjin

AU - Choi, Jaewon

AU - Lee, Howon

AU - Kwon, Sunghoon

AU - Park, Wook

PY - 2021/12/1

Y1 - 2021/12/1

N2 - We introduce highly programmable microscale swimmers driven by the Marangoni effect (Marangoni microswimmers) that can self-propel on the surface of water. Previous studies on Marangoni swimmers have shown the advantage of self-propulsion without external energy source or mechanical systems, by taking advantage of direct conversion from power source materials to mechanical energy. However, current developments on Marangoni microswimmers have limitations in their fabrication, thereby hindering their programmability and precise mass production. By introducing a photopatterning method, we generated Marangoni microswimmers with multiple functional parts with distinct material properties in high throughput. Furthermore, various motions such as time-dependent direction change and disassembly of swimmers without external stimuli are programmed into the Marangoni microswimmers.

AB - We introduce highly programmable microscale swimmers driven by the Marangoni effect (Marangoni microswimmers) that can self-propel on the surface of water. Previous studies on Marangoni swimmers have shown the advantage of self-propulsion without external energy source or mechanical systems, by taking advantage of direct conversion from power source materials to mechanical energy. However, current developments on Marangoni microswimmers have limitations in their fabrication, thereby hindering their programmability and precise mass production. By introducing a photopatterning method, we generated Marangoni microswimmers with multiple functional parts with distinct material properties in high throughput. Furthermore, various motions such as time-dependent direction change and disassembly of swimmers without external stimuli are programmed into the Marangoni microswimmers.

UR - https://www.scopus.com/pages/publications/85112007514

U2 - 10.1038/s41467-021-24996-8

DO - 10.1038/s41467-021-24996-8

M3 - Journal article

C2 - 34354060

AN - SCOPUS:85112007514

SN - 2041-1723

VL - 12

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4724

ER -

Photopatterned microswimmers with programmable motion without external stimuli

Abstract

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