Acknowledgements
Funding support from the European Community’s Seventh Framework Programme (FP7/2007-2013) under grant agreement 296679 (MANAQA) is acknowledged. S.P. acknowledges financial support by the European Research Council Starting Grant “Magnetoelectric Chemonanomotorics for Chemical and Biomedical Applications (ELECTROCHEMBOTS)”, by the ERC grant agreement no. 336456. W.W. is grateful for the financial support from National Natural Science Foundation of China (grant no. 11402069) and the city government of Shenzhen (grant no. KQCX20140521144102503). We especially thank Prof. Mahmut Selman Sakar from the Mechanical Engineering (School of Engineering, EPFL), and Carlos C. J. Alcantara from the Multi-Scale Robotics Lab (ETH Zürich) for constructive discussions.
Supporting Information
The Supporting Information is available free of charge on the ACS Publications website at 10.1021/acsnano.6b04224.
- Movie S1: A motion comparison of Au/Ru core-shell nanowires at different lengths
- Movie S2: A motion comparison among Au/Rh, Rh/Au and Au/Ru core-shell nanowires
- Supplement file: Numerical modeling procedures and additional numerical modeling results of the effect of core protrusion on the speed of nanomotors and supporting figures
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Citation
@article{jang2016,
author = {Jang, Bumjin and Wei , Wang and Samuel , Wiget and Andrew ,
Petruska and Xiangzhong , Chen and Chengzhi , Hu and Ayoung , Hong
and Folio, David and Ferreira, Antoine and Pané, Salvador and
Bradley, Nelson},
publisher = {American Chemical Society (ACS)},
title = {Catalytic {Locomotion} of {Core-Shell} {Nanowire} {Motors}},
journal = {ACS Nano},
volume = {10},
number = {11},
pages = {9983-9991},
date = {2016-10-18},
url = {https://dfolio.fr/publications/articles/2016jangACS.html},
doi = {10.1021/acsnano.6b04224},
issn = {2640-4567},
langid = {en},
abstract = {We report the partial core-shell nanowire motors. These
nanowires are fabricated using our previously developed
electrodeposition-based technique, and their catalytic locomotion in
the presence of H2O2 is investigated. Unlike conventional bimetallic
nanowires that are self-electroosmotically propelled, our Au/Ru
core-shell nanowires show both a noticeable decrease in rotational
diffusivity and increase in motor speed with nanowire length.
Numerical modelling based on self-electroosmosis attributes the
decreases in rotational diffusivity to the formation of toroidal
vortices at the nanowire tail, but fails to explain the speed
increase with length. To reconcile this inconsistency, we propose a
combined mechanism of self-diffusiophoresis and electroosmosis based
on the oxygen gradient produced by catalytic shells. This mechanism
successfully explains not only the peculiar speed increase of Au/Ru
core-shell nanomotors with length, but also the large variation in
speeds among Au/Ru, Au/Rh and Rh/Au core-shell nanomotors. The
possible contribution of diffusiophoresis to an otherwise
well-established electroosmotic mechanism sheds light on future
designs of nanomotors, at the same time highlighting the complex
nature of nanoscale propulsion.}
}