Create a controllable self-propelled hydrogel swimmer
Hydrogels remain a subject of interest due to their hydrophilic nature that allows for absorption of large volumes of water, non-toxicity, and capability to undergo both swelling and shrinkage to cater for controlled diffusions. When used as a fuel in swimmers, they allow for autonomous propul...
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| 主要作者: | |
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| 格式: | Final Year Project |
| 語言: | English |
| 出版: |
Nanyang Technological University
2022
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| 主題: | |
| 在線閱讀: | https://hdl.handle.net/10356/159126 |
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| 總結: | Hydrogels remain a subject of interest due to their hydrophilic nature that allows for
absorption of large volumes of water, non-toxicity, and capability to undergo both
swelling and shrinkage to cater for controlled diffusions. When used as a fuel in
swimmers, they allow for autonomous propulsions based off the Marangoni effect,
which makes them highly useful in potential applications such as wastewater
treatments and oil spill cleaning.
This study outlines the preparation of triangular PDMS micro-swimmers driven by
two different fuels: sodium alginate hydrogel precursor mixed with ethanol and
crosslinked alginate hydrogel infused with ethanol. The triangular PDMS swimmers
are fabricated with controlled dimensions to ensure they do not break surface tension
of the solution, which is paramount for its autonomous propulsion. The swimmers are
placed in calcium chloride solution where they swim autonomously and are recorded
to analyse their speed and swimming duration for comparison, using a particle tracking
program.
Our results reveal that the hydrogel precursor-driven swimmers outperform their
counterparts during the speed analysis, however there are inconclusive results during
the comparison of their swimming durations. Ultimately, with their enormous
amenability to customizations which can modify performances based on preferences,
these hydrogels serve as promising vehicles for autonomous pollution cleaning. |
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