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Topic Name: New Elastic circuit connectors designed for rubber-band-like circuits
Category: Electronics
Research persons: Dominique Brosteaux, Fabrice Axisa, Eva De Leersnyder, Frederick Bossuyt, Mario Gonzalez, and Jan VanfleterenBiomedical ,
Location: ELINTEC-TFCG Microsystems,Technologiepark 914,B-9052 Gent, Belgium
Details
Researchers from Belgium have devised a plan for making headway into the area
of flexible, washable electronics. These integrated electronics, which could be
incorporated into clothing and biomedical applications, require all connections
between components to stretch like rubber bands while maintaining their
conductivity.
The researchers, Dominique Brosteaux, Fabrice Axisa,
Eva De Leersnyder, Frederick Bossuyt, Mario Gonzalez, and Jan Vanfleteren, of
the Interuniversity Microelectronics Centre and Ghent University in Belgium,
have recently designed and fabricated elastic interconnections that can stretch
to more than twice their original lengths (a 100% stretchability). Their results
are published in a recent issue of IEEE Electron Device Letters.
“For biomedical and textile applications, the comfort of the user will be
enhanced if the electronic circuits are not only flexible, but also elastic,”
the researchers explained in their study. “Biomedical applications include
implantable devices and electronics on skin.”
In the paper, the scientists describe how they constructed 3-cm-long elastic
connectors by embedding 4-micrometer-thick gold wires in a highly elastic
silicone film. The wires were coated with a 2-micrometer-thick nickel layer for
soldering wires to the ends.
“Besides this construction, our team has also been developing alternative
versions of this technology based on the same molded interconnect device (MID)
technology,” Vanfleteren told .MID can combine electrical and
mechanical functions on a single unit, replacing the conventional circuit board.
The group patterned the gold wires onto a substrate in a “horseshoe”-shaped
form, which significantly reduced the stress compared with an elliptical shape,
while maintaining the initial electric resistance. The horseshoe shapes were
then connected to create a wave-like pattern. To further increase the
elasticity, the researchers found that splitting the wire conductor track into
four thinner (15-micrometer-wide) tracks greatly minimized the induced stress.
The researchers then tested a variety of different shaped connectors by
stretching them to the point of electrical failure, which is caused by a rupture
in the metallic track. The best connector stretched from 3 to 6 centimeters
without losing conductance. However, all interconnections—even those that
experienced electrical failure—recovered their conductance when they returned to
their normal length.
Currently the group is developing technology toward the incorporation of the
elastic interconnections into full electronic circuits. This goal is being
pursued by three projects: BioFlex (Biocompatible Flexible Electronic Circuits)
with STELLA (Stretchable
Electronics for Large Area Applications).
At the moment we’re focusing on the following applications: implantable
electronics, smart textiles (with integrated stretchable circuits), and smart
band aids (e.g. measuring physiological parameters that should follow skin
deformations),” Vanfleteren said, adding that further details remain
confidential at this time.
About Researchers-
|
ir. Dominique Brosteaux
TFCG microsystems
Affiliated with IMEC vzw |
ELINTEC-TFCG
Technologiepark 914
B-9052 Gent, Belgium |
tel : + 32-9-264.53.69
fax : +32-9-264.53.74
e-mail: Dominique.Brosteaux"at"elis.ugent.be |
|
Dr. Fabrice Axisa
TFCG microsystems
Affiliated with IMEC vzw |
ELINTEC-TFCG
Technologiepark 914
B-9052 Gent, Belgium |
tel : + 32-9-264.53.54
fax : +32-9-264.53.74
e-mail: Fabrice.Axisa@elis.ugent.be |
|
Dr. ir. Jan Vanfleteren
TFCG microsystems
Affiliated with IMEC vzw |
ELINTEC-TFCG
Technologiepark 914
B-9052 Gent, Belgium |
tel : + 32-9-264.53.60
fax : +32-9-264.53.74
e-mail: Jan.Vanfleteren@elis.ugent.be |
TFCG Microsystems Lab "@ a glance"
The TFCG Microsystems Lab is a centre for smart microsystems integration,
focusing on design as well as technology research in 5 domains:
The envisaged applications include telecom, wireless sensors, robotics,
biomedics, health care, training, simulation, entertainment and smart textile.
TFCG Microsystems lab is affiliated with IMEC vzw.
Funded-
TFCG Microsystems lab is affiliated with funding
by the Institute for the Promotion of Innovation by
Science and Technology in Flanders,
European Commission; and
SWEET (Stretchable
and Washable Electronics for Embedding in Textiles) with funding by the
Belgian Science Policy.
In The Images-
A goal
of the SWEET project is to design electronics that are not only elastic, but
also washable, as demonstrated by this water-resistant, stretchable LED circuit.
Credit: Jan Vanfleteren, et al. (TFCG Microsystems Lab-Ghent University)
2.This stretchable thermometer can wrap around a patient’s forehead like a
headband thanks to the horseshoe-shaped metal wires, which can stretch up to
twice their normal lengths. Credit: Jan Vanfleteren, et al. (TFCG Microsystems
Lab-Ghent University
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