Sage Journals: Discover world-class research

Abstract

Micro and nanoscale mobile agents capable of self-propulsion in low Reynolds number fluids would have a great technological impact in many fields. Few known mechanisms are able to propel such devices. Here we describe helical nanobelt (HNB) swimmers actuated by an electric field-generated electro-osmotic force. These HNB swimmers are designed with a head and a tail, similar to natural micro-organisms such as bacteria and their flagella. We show that these electro-osmotic propulsion of HNB swimmers achieve speeds (24 body lengths per second), force (1.3 nN), and pressure (375.5 Pa) above those demonstrated by other artificial swimmers based on physical energy conversion. Although nature’s bacteria are still more dynamic, this paper reports that the demonstrated electro-osmotic HNB microswimmers made a big step toward getting closer to their performances. Moreover, an unusual swimming behavior with discontinuous pumping propulsion, similar to jellyfish, was revealed at or above the speculated marginal limit of linear propulsion. These electro-osmosis propelled HNB swimmers might be used as biomedical carriers, wireless manipulators, and as local probes for rheological measurements.

Keywords

Biologically inspired robots biomimetics human-centered and life-like robotics mechanics design and control micro/nanorobots

Get full access to this article

View all access options for this article.

References

Acosta JC , Hwang G. , Polesel-Maris J and Régnier S (2011) A tuning fork based wide range mechanical characterization tool with nanorobotic manipulators inside a scanning electron microscope. Review of Scientific Instruments 82(3): 035116.

Abbott JJ , Peyer KE , Lagomarsino MC , Zhang L. , Dong LX , Kaliakatsos IK , et al. (2009) How should microrobots swim? International Journal of Robotics Research 28(11-12): 1434-1447.

Behkam B. and Sitti M. ( 2006) Bacterial flagella-based propulsion and on/off motion control of microscale objects. Applied Physics Letters 90(2): 023902(1-3).

Bell DJ , Dong LX , Nelson BJ , Golling M. , Zhang L. and Grutzmacher D. ( 2006) Fabrication and Characterization of three-dimensional InGaAs/GaAs nanosprings. Nano Letters 6(4): 725-729.

Bell DJ , Leutenegger S. , Hammar KM , Dong LX and Nelson BJ ( 2007) Flagella-like propulsion for microrobots using a magnetic nanocoil and rotating electromagnetic field. In: Proceedings of the IEEE International Conference on Robotics and Automation , pp. 1128-1133.

Berg HC ( 2004) E. coli in Motion. New York: Springer.

Berg HC and Brown DA ( 1972) Chemotaxis in Escherichia coli analysed by three-dimensional tracking. Nature 239(5374): 500-504.

Berkow R. ( 1997) Electrical injuries. In: The Merck Manual of Medical Information: Home Edition. New York: Merck.

Chang ST , Beaumont E. , Petsev DN and Velev OD ( 2007b) Remotely powered distributed microfluidic pumps and mixers based on miniature diodes. Lab on a Chip 8: 117-124.

10.

Chang ST , Paunov VN , Petsev DN and Velev OD ( 2007a) Remotely powered self-propelling particles and micropumps based on miniature diodes. Nature Materials 6(3): 235-240.

11.

Dreyfus R. , Baudry J. , Roper ML , Fermigier M. , Stone HA and Bibette J. ( 2005) Microscopic artificial swimmers. Nature 437(6): 862-865.

12.

Gao PX , Mai W. and Wang ZL ( 2006) Superelasticity and nanofracture mechanics of ZnO Nanohelices . Nano Letters 6(11): 2536-2543.

13.

Ghosh A. and Fischer P. (2009) Controlled propulsion of artificial magnetic nanostructured propellers . Nano Letters 9(6): 2243-2245.

14.

Honda T. , Arai KI and Ishiyama K. ( 1996) Micro swimming mechanisms propelled by external magnetic fields. IEEE Transactions on Magnetics 32(5): 5085-5087.

15.

Hunter RJ ( 2001) Foundations of Colloid Science. New York: Oxford University Press.

16.

Hwang G. , Hashimoto H. , Bell DJ , Dong LX , Nelson BJ and Schon S (2009) Piezoresistive InGaAs/GaAs nanosprings with metal connectors. Nano Letters 9(2): 554-561.

17.

Ishiyama K. , Arai KI , Sendoh M. and Yamazaki A. ( 2003) Spiral-type micro-machine for medical applications. Journal of Micromechatronics 2(1): 77-86.

18.

Kosa G. , Jakab P. , Hata N. , Jolesz F. , Neubach Z. , Shoham M. , et al. (2008) Flagella swimming for medical micro robots: theory, experiments and application. In: Proceedings of the 2nd IEEE RAS-EMBS International Conference on Biomedical Robotics and Biomechatronics, pp.258-263.

19.

Laocharoensuk R. , Burdick J. and Wang J. ( 2008) Carbonnanotube-induced acceleration of catalytic nanomotors . ACS Nano 2(5): 1069-1075.

20.

Little WC , Smith ML , Ebneter U. and Vogel V. ( 2008) Assay to mechanically tune and optically probe fibrillar fibronectin conformations from fully relaxed to breakage. Matrix Biology 27(5): 451-461.

21.

Martel S. , Felfoul O. , Mathieu J. , Chanu A. , Tamaz S. , Mohammadi M. , et al. (2009b) MRI-based medical nanorobotic platform for the control of magnetic nanoparticles and flagellated bacteria for target interventions in human capillaries. The International Journal of Robotics Research 28: 1169-1182.

22.

Martel S. , Tremblay C. , Ngakeng S. and Langlois G. ( 2006) Controlled manipulation and actuation of micro-objects with magnetotactic bacteria. Applied Physics Letters 89: 233804- 233806

23.

Martel S. , Tremblay C. , Ngakeng S and Langlois G (2009a) Flagellated magnetotactic bacteria as controlled MRI-trackable propulsion and steering systems for medical nanorobots operating in the human microvasculature. The International Journal of Robotics Research 28: 571-582.

24.

Mei YF , Huang G. , Solovev AA , Urena EB , Monch IM , Ding F. , et al. (2008) Versatile approach for integrative and functionalized tubes by strain engineering of nanomembranes on polymers. Advanced Materials 20: 4085-4090.

25.

Park SJ , Goodman MB and Pruitt BL ( 2007) Analysis of nematode mechanics by piezoresistive displacement clamp. Proceedings of the National Academy of Sciences of United States of America 104(44): 17376-17381.

26.

Purcell EM ( 1977) Life at low Reynolds number. American Journal of Physics 45(1): 3-11.

27.

Steager E. , Kim CB , Naik C. , Patel J. , Bith S. , Reber L. , et al. (2007) Control of microfabricated structures powered by flagellated bacteria using phototaxis. Applied Physics Letters 90(26): 263901(1-3).

28.

Sundararajan S. , Lammert PE , Zudans AW , Crespi VH and Sen A. ( 2008) Catalytic motors for transport of colloidal cargo. Nano Letters 8(5): 1271-1276.

29.

Solovev AA , Mei YF , Urena BE , Huang G and Schmidt OG (2009) Catalytic microtubular jet engines self-propelled by accumulated gas bubbles. Small 5(14): 1688.

30.

Turner D. ( 1902) The electrical resistance of the blood. Nature 66(1701): 127.

31.

Turner L. , Ryu WS and Berg HC ( 2000) Real-time imaging of fluorescent flagellar filaments. Journal of Bacteriology 182(10): 2793-2801.

32.

Varoutsis S. , Laurent S. , Sagnes I. , Lemaitre A. , Ferlazzo L. , Mériadec C. , et al. (2005) Reactive-ion etching of high-Q and submicron-diameter GaAs/AlAs micropillar cavities. Journal of Vacuum Science & Technology B 23(6): 2499-2503.

33.

Wang ZL and Song JH ( 2006) Piezoelectric nanogenerators based on zinc oxide nanowire arrays. Science 312: 242-246.

34.

Xu S. , Qin Y. , Xu C. , Wei Y. , Yang R. and Wang ZL ( 2010) Self-powered nanowire devices. Nature Nanotechnology 5: 366-373.

35.

Zhang L. , Abbott JJ , Dong LX , Kratochvil BE , Bell D. and Nelson BJ ( 2009a) Artificial bacteria flagella: fabrication and magnetic control. Applied Physics Letters 94(6): 064107(1-3).

36.

Zhang L. , Abbott JJ , Dong LX , Peyer KE , Kratochvil BE , Zhang H. , et al. (2009b) Characterizing the swimming properties of artificial bacterial flagella. Nano Letters 9(10): 3663-3667.

37.

Zhang L. , Peyer KE and Nelson BJ (2010) Artificial bacteria flagella for micromanipulation . Lab on a Chip 10(17): 2203-2215.

38.

Zhang L. , Ruh E. , Grutzmacher D. , Dong LX , Bell DJ , Nelson BJ , et al. (2005) Controllable fabrication of SiGe/Si and SiGe/Si/Cr helical nanobelts. Nanotechnology 16: 655-663.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB