31 May 2018
For the journal paper, please click: http://robotics.sciencemag.org/content/3/18/eaat4051.full
Professor Alfonso Ngan and Dr Kwan Kin-wa introduce the
new actuating material powered by light.
new actuating material powered by light.
To develop micro- and biomimetic-robots, artificial muscles and medical
devices, actuating materials that can reversibly change their volume
under various stimuli are researched in the past thirty years to replace
traditional bulky and heavy actuators including motors and pneumatic
actuators.
A mechanical engineering team led by Professor Alfonso Ngan Hing-wan,
Chair Professor in Materials Science and Engineering, and Kingboard
Professor in Materials Engineering, Faculty of Engineering, the
University of Hong Kong (HKU) published an article in Science Robotics
on 30 May 2018 (EST) that introduces a novel actuating material –
nickel hydroxide-oxyhydroxide – that can be powered by visible (Vis)
light, electricity, and other stimuli. The material actuation can be
instantaneously triggered by Vis light to produce a fast deformation and
exert a force equivalent to 3000 times of its own weight. The material
cost of a typical actuator is as low as HKD 4 per cm2 and can be easily fabricated within three hours.
Among various stimuli, light-induced actuating materials are highly
desirable because they enable wireless operation of robots. However,
very few light driven materials are available in the past, and their
material and production costs are high, which hinder their development
in actual applications such as artificial muscles for robotics and human
assist device, and minimally invasive surgical and diagnostic tools.
Developing actuating materials was identified as the top of the 10 challenges in “The grand challenges of Science Robotics”1.
Research in actuating materials can radically change the concept of
robots which are now mainly motor-driven. Therefore, materials that can
be actuated by wireless stimuli including a change in temperature,
humidity, magnetic fields and light is one of the main research focus in
recent years. In particular, a material that can be actuated by Vis
light and produces strong, quick and stable actuation has never been
achieved. The novel actuating material system – nickel
hydroxide-oxyhydroxide that can be actuated by Vis light at relatively
low intensity to produce high stress and speed comparable to mammalian
skeletal muscles has been developed in this research initiated by
engineers in HKU.
In addition to its Vis light actuation properties, this novel material
system can also be actuated by electricity, enabling it to be integrated
into the present well-developed robotics technology. It is also
responsive to heat and humidity changes so that they might potentially
be applied in autonomous machines that harness the tiny energy change in
the environment. Because the major component is nickel, the material
cost is low. The fabrication only involves electrodeposition which is a
simple process, and the time required for the fabrication is around
three hours, therefore the material can be easily scaled up and
manufactured in industry.
The newly invented nickel hydroxide-oxyhydroxide responses to light
almost instantaneously and produces a force corresponding to about 3000
times of its own weight (Figure 1).
1 Yang, Guang-Zhong, et al. "The grand challenges of Science Robotics." Science Robotics 3.14 (2018): eaar7650.
1 Yang, Guang-Zhong, et al. "The grand challenges of Science Robotics." Science Robotics 3.14 (2018): eaar7650.
Figure 1 Actuating force of a 0.3-mg nickel hydroxide-oxyhydroxide actuator of under periodic light can reach about 1000-mg.
When integrated into a well-designed structure, a “mini arm” made by
two hinges of actuating materials can easily lift an object 50 times of
its weight (Figure 2). Similarly, by utilizing a light blocker, a mini
walking-bot in which only the “front leg” bent and straighten
alternatively and therefore moves under illumination was made so that it
can walk towards the light source (Figure 3). These demonstrate that
future applications in micro-robotics including rescue robots are
possible.
Figure 2 A mini arm with two actuating hinges lifting a weight 50 time heavier than itself under light.
Figure 3 A mini walking-bot with the “front leg”
straightened under light, while the light blocker blocks the light
illumination on the “back leg” and therefore it remains curled.
Therefore, the walking-bot walks towards the light source.
The evidences above revealed that this nickel hydroxide-oxyhydroxide
actuating material can have different applications in the future,
including rescue robots or other mini-robots. The intrinsic actuating
properties of the materials obtained from our research show that by
scaling up the fabrication, artificial muscles comparable to that of
mammalian skeletal muscles can be achieved, and applying it in robotics,
human assist device and medical devices are possible.
From a scientific point of view, this nickel hydroxide-oxyhydroxide
actuating material is the world’s first material system that can be
actuated directly by Vis light and electricity without any additional
fabrication procedures. This also opens up a new research field on
light-induced actuating behaviour for this material type
(hydroxide-oxyhydroxides) because it has never been reported before.
The research team members are all from the Department of Mechanical
Engineering at HKU Faculty of Engineering, led by Professor Alfonso
Ngan’s group in collaboration with Dr Li Wen-di. ’s group on light
actuation experiment and Dr Feng Shien-ping’s group on electrodeposition
experiment. The research has been published in the prestigious
journal Science Robotics on 30 May 2018 with a title of
“Light-stimulated actuators based on nickel hydroxide-oxyhydroxide”. The
first author of this paper is Dr Kwan Kin-wa who is currently a
post-doctoral fellow in Prof. Ngan’s group. The corresponding author is
Prof. Ngan. The complete author list is as below: K-W. Kwan, S-J. Li,
N-Y. Hau, W-D. Li, S-P. Feng, A.H.W. Ngan. This research is funded by
the Research Grants Council, Hong Kong.
For the powerpoint slides about this research, please click here, and for video clips, please click here. (Please credit “The University of Hong Kong” if adopt the images in the powerpoint and videos.)
Media enquiry:
Faculty of Engineering:
Dr Kwan Kin-wa (Email: kkwkwan@connect.hku.hk)
Professor Alfonso Ngan (Tel: 39177900; Email: hwngan@hku.hk)
Ms Rhea Leung (Tel: 3917-8519/ 9022-7446; Email: rhea.leung@hku.hk)
Communication and Public Affairs Office:
Ms Trinni Choy (Tel: 2859 2606/ Email: pychoy@hku.hk)
Ms Rashida Suffiad (Tel: 2857 8555/ email: rsuffiad@hku.hk)
Faculty of Engineering:
Dr Kwan Kin-wa (Email: kkwkwan@connect.hku.hk)
Professor Alfonso Ngan (Tel: 39177900; Email: hwngan@hku.hk)
Ms Rhea Leung (Tel: 3917-8519/ 9022-7446; Email: rhea.leung@hku.hk)
Communication and Public Affairs Office:
Ms Trinni Choy (Tel: 2859 2606/ Email: pychoy@hku.hk)
Ms Rashida Suffiad (Tel: 2857 8555/ email: rsuffiad@hku.hk)
