| Abstract |
Untethered mobile microrobots have the unique capability of accessing to small spaces and scales
directly. Due to their small size and micron-scale physics and dynamics, they could be agile and
portable, and could be inexpensive and in large numbers if they are mass-produced. Mobile
microrobots would have high impact applications in health-care, bioengineering, mobile sensor
networks, desktop micromanufacturing, and inspection. In this presentation, synthetic and
bio-hybrid mobile microrobots from few micrometers up to hundreds of micrometer overall sizes and
various locomotion capabilities are presented.
Going down to micron scale, one of the grand challenges for mobile microrobots is
miniaturization limitation on on-board actuation, powering, sensing, processing, and communication
components. Two alternative approaches are explored in this talk to solve the actuation and
powering challenges. First, biological cells, e.g. bacteria, attached to the surface of a synthetic
microrobot are used as on-board microactuators and microsensors using the chemical energy inside or
outside the cell in physiological fluids. Bacteria-propelled microswimmers are steered using
chemical and pH gradients in the environment and remote magnetic fields towards future targeted
drug delivery and environmental remediation applications. As the second approach, external
actuation of untethered magnetic microrobots using remote magnetic fields in enclosed spaces is
demonstrated. New magnetic microrobot locomotion principles based on rotational stick-slip and
rolling dynamics are proposed. Novel magnetic composite materials are used to address and control
teams of microrobots. Such untethered microrobot teams are demonstrated to manipulate live cells
and microgels with embedded cells for bioengineering applications, and to self-assemble into
different patterns with remote magnetic control.
Speaker's Bio:
Metin Sitti received the BSc and MSc degrees in electrical and electronics engineering from
Bogazici University, Istanbul, Turkey, in 1992 and 1994, respectively, and the PhD degree in
electrical engineering from the University of Tokyo, Tokyo, Japan, in 1999. He was a research
scientist at UC Berkeley during 1999-2002. He is currently a director in Max-Planck Institute for
Intelligent Systems and a professor in Department of Mechanical Engineering and Robotics Institute
at Carnegie Mellon University. His research interests include small-scale physical intelligence,
mobile microrobots, bio-inspired millirobots, smart and soft micro/nanomaterials, and programmable
self-assembly. He is an IEEE Fellow. He received the SPIE Nanoengineering Pioneer Award in 2011 and
NSF CAREER Award in 2005. He received the IEEE/ASME Best Mechatronics Paper Award in 2014, the Best
Poster Award in the Adhesion Conference in 2014, the Best Paper Award in the IEEE/RSJ International
Conference on Intelligent Robots and Systems in 2009 and 1998, the first prize in the World RoboCup
Micro-Robotics Competition in 2012 and 2013, the Best Biomimetics Paper Award in the IEEE Robotics
and Biomimetics Conference in 2004, and the Best Video Award in the IEEE Robotics and Automation
Conference in 2002. He is the editor-in-chief of Journal of Micro-Bio Robotics.
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