Jaewan KIM -- electro-active cellulose -- Paper muscle

  

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Jaewan KIM  
Electroactive Paper

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<http://www.eapap.com>  
[http://www.technologyreview.com/articlefiles/17127-bourzac
070706](http://www.technologyreview.com/articlefiles/17127-bourzac%20070706)  
Friday,
July 07, 2006  

# Moving Paper Parts for Robots

Cellulose films could provide flapping wings
and cheap artificial muscles for robots.

by Katherine
Bourzac

![](paper%20muscle.jpg)

  
( This thin film of gold-coated
cellulose flaps like dragonfly wings in response to an
electrical current. The material, called electroactive paper,
may serve as wings for small flying robots. (Courtesy of
Zoubeida Ounaies, Texas A&M University. )   
  
Researchers at Inha University in South Korea have demonstrated
that cellulose, the main ingredient in paper, can bend in response
to electricity. The treated cellulose is lightweight, inexpensive,
and has low power requirements, compared with similar electrically
active materials. The Korean researchers are now working with NASA
to develop insect-sized, wirelessly powered flying vehicles with
flapping paper wings. Such vehicles could fly into areas unsafe
for humans and test for hazardous gases -- or survey the surface
of Mars from the air.   
  
The researchers, led by Jaehwan Kim (http://www.eapap.com ) ,
associate professor at the university, made the electrically
active cellulose by dissolving paper pulp, forming it into sheets,
and coating it with a layer of gold as an electrode. Some areas of
the cellulose film are highly ordered, while in other areas, the
cellulose strands are tangled like spaghetti. The movement of ions
through the paper -- and the movement of cellulose strands
themselves, which have negative and positively charged ends --
causes the paper to bend in response to an electrical current. The
bending is driven by the ordered regions, but free space in
disordered regions allows ions to flow more freely and adds to the
paper's ability to deform.   
  
Materials that move in response to electrical current are called
piezoelectrics. Kim's cellulose is one of a new class of these
materials, called electroactive polymers, that have generated
excitement in the scientific community for their potential uses in
many areas: artificial muscles, chemical sensors, visual displays,
the moving parts of robots, and batteries.   
  
"The value of electrically active paper is that it's lightweight
and has a high deflection [movement] at low voltage" compared to
traditional electroactive polymers, says Sang Choi, senior
research scientist at the NASA Langley Research Center. When a
small voltage is applied to Kim's paper, it can move a relatively
large distance; for instance, in experiments, the tip of a
30-millimeter-long strip of electroactive paper was displaced 4.2
millimeters. Indeed, the strength of the electric field required
to move the tip of the paper to its maximum displacement is one to
two orders of magnitude less than is required by other
electroactive polymers. And the paper can change shape quickly,
moving back and forth as fast as once every 0.06 seconds.   
  
NASA's Choi is interested in Kim's material because, compared with
conventional piezoelectrics and other electroactive polymers, it
is very lightweight and requires very little power. Together, Choi
and Kim are designing a small flying vehicle with cellulose wings
powered by ambient microwaves. Choi says NASA expects such robots
to play an important role in its long-term exploratory missions.
For example, small robots with moving parts made of paper or other
materials might fly low over the Martian surface to monitor its
topology. Still, it's not clear that cellulose can withstand the
extreme conditions in outer space. ---   
  

![](dn9319-1_250.jpg)

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KR20090087280
  
PIEZOELECTRIC PAPER AND THE METHOD THEREOF$

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US2006042541   
Method for Preparation of
Ferroelectric Single Crystal Film Structure using Deposition
Method

Inventor: EUN JAEHWAN (KR); LEE
SANG-GOO (KR); KIM HYEONGJOON (KR); KIM MINCHAN (KR)

Also published as: // WO2004055876
(A1) // AU2003302958 (A1)

Abstract
--- A film structure of a ferroelectric single crystal which can
be beneficially used in the fabrication of high-performance
electric and electronic parts and devices is prepared by forming
an electrode layer having a perovskite crystal structure on a
substrate made of a silicon or ferroelectric single crystal
optionally polished to have a off-axis crystal structure, and
epitaxially growing a layer of a ferroelectric single crystal
thereon by pulsed laser deposition (PLD) or metallorganic chemical
vapor deposition (MOCVD).



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<http://www3.interscience.wiley.com/journal/114278287/abstract?CRETRY=1&SRETRY=0>

Macromolecular
Materials
and Engineering, Volume 292 Issue 6, Pages 748 - 753  
  
<http://www3.interscience.wiley.com/journal/10048709/home>

Electroactive Paper Actuator Made with
Chitosan-Cellulose Films: Effect of Acetic Acid

  
Niangui Wang, Yi Chen, Jaehwan Kim \*

Center for EAPap Actuator, Department
of Mechanical Engineering, Inha University, 253 Yonghyun-Dong,
Nam-Ku, Incheon 402-751, South Korea  
email: Jaehwan Kim (jaehwan@inha.ac.kr)  
  
\*Correspondence to Jaehwan Kim, Center for EAPap Actuator,
Department of Mechanical Engineering, Inha University, 253
Yonghyun-Dong, Nam-Ku, Incheon 402-751, South Korea. Fax: (+82) 32
868 1716  
  
Abstract --- This paper
introduces an electroactive paper (EAPap) prepared with cellulose
and chitosan films. The fabrication process, performance test, and
the effect of acetic acid dosage of the EAPap were investigated.
For the fabrication of cellulose EAPap, cellulose fibers were
dissolved into a solution using N,N-dimethylacetamide and lithium
chloride. The solution was cast and immersed in water to form a
cellulose film, followed by casting chitosan/acetic acid and
glycerol aqueous solutions on the cellulose film. A bending EAPap
actuator was made by depositing thin gold electrodes on both sides
of the cellulose film. The bending displacement of the EAPap
actuators was evaluated with respect to voltage, frequency,
humidity, and acetic acid dosage. An optimum mole ratio of the
acetic acid and chitosan structure unit was found. Also, the
effects of chitosan and acetic acid on the actuation behavior of
the cellulose-chitosan laminated films were investigated.

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<http://www3.interscience.wiley.com/journal/114210248/abstract>  
Polymer International, Volume 56
Issue 12, Pages 1530 - 1536

Synthesis,
characterization
and actuation behavior of polyaniline-coated electroactive paper
actuators  
Jaehwan Kim 1 \*, Sung-Ryul Yun 1,
SD Deshpande 1 2

1Center for EAPap Actuator and
Department of Mechanical Engineering, Inha University, Incheon
402-751, South Korea  
2National Chemical Laboratory, Chemical Engineering Division, Pune
- 41108, India  
email: Jaehwan Kim (jaehwan@inha.ac.kr)  
\*Correspondence to Jaehwan Kim, Center for EAPap Actuator,
Department of Mechanical Engineering, Inha University, 253
Yonghyun-Dong, Nam-Gu, Incheon 402-751, South Korea  
  
Abstract -- This
investigation deals with the synthesis, characterization and
actuation behavior of conductive polyaniline-coated electroactive
paper actuators. The actuator is made by electrochemical
deposition of conductive polyaniline on a cellulose paper. The aim
of the investigation was to improve the bending displacement of
electroactive paper actuators. The displacement outputs of the
actuators show that a trilayer is better than a bilayer
configuration. The nature of the dopant ion used in the
electro-generation affects the performance. A change in humidity
plays a vital role in actuation performance of the actuators.
Comparing the performance of electroactive paper actuators with
and without a conductive polyaniline coating, the coating improves
the displacement output threefold. Finally, the actuation
principle mechanism is addressed.

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<http://www.newscientist.com/article/dn9319-smart-paper-may-put-lightweight-spies-in-the-skies.html>

Smart paper may put lightweight spies in the
skies  
  
by   
  
Tom Simonite

Paper aeroplanes could fly by flapping their wings thanks to smart
paper that bends when bathed in an electric field. The material
raises the prospect of swarms of tiny lightweight aircraft
carrying sensors that act as the eyes and ears of a surveillance
network.  
  
Electroactive paper (EAPap) is ordinary cotton-based paper,
similar to the material used to make US bank notes, coated on each
side with a thin layer of gold. The smart paper has been made by
researchers from Inha University, South Korea, and Texas A & M
University, US  
  
Unlike ordinary paper, EAPap bends as a result of two effects
working together. When a voltage is applied, the gold coating on
one side of the paper becomes a positively charged while the other
side becomes negatively charged. Sodium ions in the paper move
towards the negative electrode, taking water molecules with them.
This makes that side of the paper expand, causing it to bend.  
  
At the same time, the paper's matrix of cellulose fibres have
piezoelectric properties and change shape when a voltage is
applied. This increases the bending. The research team have even
improved the paper's piezoelectric properties even further by
adding carbon nanotubes to the paper mix.

Artificial
muscle  
  
The team has made strips of paper 40 millimetres long and 0.3 mm
thick that bend by 10 mm, producing a force of more than 10
micronewtons. That is enough to lift about 1 gram.  
  
"This new discovery of cellulose paper as a smart material gives
us a lot of possibilities that we can play around with," Jaehwan
Kim, who researches smart materials at Inha University.  
  
Kim's team is interested in using the material as a kind of
artificial muscle for mobile robots. He hopes to power the robots
remotely by fitting them with a simple electronic device called a
"rectenna". This converts the energy of a microwave beam into a
small voltage.  
Flying sensors  
  
"A normal paper aeroplane just flies as it is," says Jaehwan Kim.
"By sending microwaves we could control its wings and make it
glide in a certain path."  
  
Another possibility is a robot in the form of a rippling sheet of
EAPap that crawls along the ground. As well as working on boosting
the power of EAPap, the Korean team is collaborating with NASA to
develop the rectenna system to drive it.  
  
"This new material opens up a whole range of possible
applications," says Djamel Azzi, a robotics researchers at
Portsmouth University, UK. "Lightweight flying robots would be
ideal for surveillance - they could carry cameras, microphones or
other sensors around."

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<http://adsabs.harvard.edu/abs/2008SPIE.6927E..47C>

Cellulose-chitosan
blended
electroactive paper actuator  
Cai, Zhijiang; Chen, Yi; Kim,
Jaehwan

Electroactive Polymer Actuators and
Devices (EAPAD) 2008. Edited by Bar-Cohen, Yoseph. Proceedings
of the SPIE, Volume 6927, pp. 69271H-69271H-7 (2008).

Cellulose based Electro-Active Paper (EAPap) has been reported as
a smart material that has merits in terms of lightweight, dry
condition, biodegradability, sustainability, large displacement
output and low actuation voltage. However, its actuator
performance is sensitive to humidity: its maximum bending
performance was shown at high humidity condition. To overcome this
drawback, we introduce an EAPap made with cellulose and chitosan
blend. Cellulose-chitosan blend films with varied mixing ratio
were prepared by dissolving the polymers in trifluoroacetic acid
as a co-solvent followed by spincoating onto glass substrates. A
bending EAPap actuator is made by depositing thin gold electrodes
on both sides of the cellulose-chitosan films. The performance of
the EAPap actuator is evaluated in terms of free bending
displacement with respect to the actuation frequency, activation
voltage, humidity level and content of chitosan. The actuation
principle is also discussed.

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<http://www.springerlink.com/content/x7788q7183806661/>  
Cellulose,     Volume 14, Number 3 / June, 2007

Electroactive-paper actuator made with
cellulose/NaOH/urea and sodium alginate

Jaehwan
Kim1,
Niangui Wang1, Yi Chen1, Sun-Kon Lee1 and Gyu-Young Yun1

(1)      Creative
Research Center for EAPap Actuator, Mechanical Engineering
Department, Inha University, 253 Yonghyun-Dong, Nam-Ku, Incheon,
402-751, South Korea  
  
Received: 11 July 2006  Accepted: 10 January 2007 
Published online: 14 February 2007  
Abstract  In an earlier work we reported the discovery of
cellulose as a smart material that can be used in sensors and
actuators. While the cellulose-based Electro-Active Paper (EAPap)
actuator has many merits  lightweight, dry condition,
biodegradability, sustainability, large displacement output and
low actuation voltage  its performance is sensitive to humidity.
We report here on an EAPap made with a cellulose and sodium
alginate that produces its maximum displacement at a lower
humidity level than the earlier one. To fabricate this EAPap, we
dissolved cellulose fibers into a aqueous solution of NaOH/urea.
Sodium alginate (0, 5 or 10% by weight) was then added to this
cellulose solution. The solution was cast into a sheet and
hydrolyzed to form a wet cellulose-sodium alginate blend film.
After drying, a bending EAPap actuator was made by depositing thin
gold electrodes on both sides of it. The performance of the EAPap
actuator was then evaluated in terms of free displacement and
blocked force with respect to the actuation frequency, activation
voltage and content of sodium alginate. The actuation principle is
also discussed.

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<http://cat.inist.fr/?aModele=afficheN&cpsidt=18834275>  
Macromolecular Materials and
Engineering,  2007, vol. 292, no6, pp. 748-753

Electroactive paper actuator made with
chitosan-cellulose films: Effect of acetic acid

NIANGUI
WANG
(1) ; YI CHEN (1) ; KIM Jaehwan (1)

(1) Center for EAPap Actuator,
Department of Mechanical Engineering, Inha University, 253
Yonghyun-Dong, Nam-Ku, Incheon 402-751, COREE, REPUBLIQUE DE

Abstract
-- This paper introduces an electroactive paper (EAPap)
prepared with cellulose and chitosan films. The fabrication
process, performance test, and the effect of acetic acid dosage of
the EAPap were investigated. For the fabrication of cellulose
EAPap, cellulose fibers were dissolved into a solution using
N,N-dimethylacetamide and lithium chloride. The solution was cast
and immersed in water to form a cellulose film, followed by
casting chitosan/acetic acid and glycerol aqueous solutions on the
cellulose film. A bending EAPap actuator was made by depositing
thin gold electrodes on both sides of the cellulose film. The
bending displacement of the EAPap actuators was evaluated with
respect to voltage, frequency, humidity, and acetic acid dosage.
An optimum mole ratio of the acetic acid and chitosan structure
unit was found. Also, the effects of chitosan and acetic acid on
the actuation behavior of the cellulose-chitosan laminated films
were investigated.

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<http://www.iop.org/EJ/abstract/0964-1726/14/4/048>

2005
Smart Mater. Struct. 14 876-880

Studies on conducting polymer electroactive paper
actuators: effect of humidity and electrode thickness  
  
S D Deshpande, et al.

 S D Deshpande1,2, Jaehwan Kim1,3
and Sung-Ryul Yun1

1 Creative Research Center for EAPap
Actuator, Mechanical Engineering Department, Inha University,
Incheon 402-751, Korea  
2 National Chemical Laboratory, Chemical Engineering Division,
Pune-41108, India  
3 Author to whom any correspondence should be addressed  
E-mail: jaehwan@inha.ac.kr  
  
Abstract -- Actuators
based on cellulose paper with conducting polymer (CP-EAPap) as an
electrode material were constructed. The bilayer and trilayer
types of actuators were fabricated by depositing conducting
polypyrrole on one side and two sides of cellophane paper
respectively, which was previously gold coated. By varying the
deposition time, the electrode thickness was manipulated. The
performance of these two types of actuators was compared with
respect to humidity changes and thickness variation. The electrode
thickness plays a key role in the displacement behavior of these
types of actuators. The best performance at higher humidity is
also characteristic of CP-EAPap actuators. The possible mechanism
of actuation is addressed in this paper.

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<http://www.ingentaconnect.com/content/klu/cell/2007/00000014/00000003/00009111>

Cellulose,
Volume
14, Number 3, June 2007 , pp. 217-223(7)

Electroactive-paper actuator made with
cellulose/NaOH/urea and sodium alginate

Authors:
Kim,
Jaehwan1; Wang, Niangui; Chen, Yi; Lee, Sun-Kon; Yun, Gyu-Young

Abstract
-- In an earlier work we reported the discovery of cellulose as a
smart material that can be used in sensors and actuators. While
the cellulose-based Electro-Active Paper (EAPap) actuator has many
merits - lightweight, dry condition, biodegradability,
sustainability, large displacement output and low actuation
voltage - its performance is sensitive to humidity. We report here
on an EAPap made with a cellulose and sodium alginate that
produces its maximum displacement at a lower humidity level than
the earlier one. To fabricate this EAPap, we dissolved cellulose
fibers into a aqueous solution of NaOH/urea. Sodium alginate (0, 5
or 10% by weight) was then added to this cellulose solution. The
solution was cast into a sheet and hydrolyzed to form a wet
cellulose-sodium alginate blend film. After drying, a bending
EAPap actuator was made by depositing thin gold electrodes on both
sides of it. The performance of the EAPap actuator was then
evaluated in terms of free displacement and blocked force with
respect to the actuation frequency, activation voltage and content
of sodium alginate. The actuation principle is also discussed.

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<http://pubs.acs.org/doi/abs/10.1021/jp067012c>

Electric Field Frequency and
Strength Effects on Au-Electrode Damage for an Electroactive
Paper Actuator Coated with Polypyrrole

K. Y. Cho, H. G. Lim, S. R. Yun, Jaehwan Kim, and K. S. Kang\*  
Creative Research Center for Electroactive Paper (EAPap) Actuator,
Mechanical Engineering Department, Inha University 253
Yonghyun-Dong Nam-Ku 402-751, Incheon, South Korea  
J. Phys. Chem. C, 2008, 112 (17), pp 70017004  
  
To whom correspondence should be addressed. E-mail:  kkang@
inha.ac.kr.

Abstract
-- The causes of Au-electrode damage to an electroactive paper
(EAPap) actuator coated with Au and polypyrrole (PPy) were
investigated with various electric field frequencies and
strengths. The resonance frequency of 3.5 Hz was obtained for 3
and 4 V. Electric field frequencies below (2 Hz) the resonance
frequency yielded a faster bending displacement reduction than
those of the higher resonance frequency. High electric field
strength (4 V) shows a faster reduction of bending displacement
than lower field strength (3 V). The degree of Au-electrode damage
after a certain period of actuation is shown in field emission
scanning electron microscope (FESEM) images. The electric field
strength and frequency and bending displacement reduction were
found to be closely related to the degree of Au-electrode damage.

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<http://linkinghub.elsevier.com/retrieve/pii/S0924424709002465>

Au pattern fabrication on a cellulose paper using
micro-contact ...

Creative Research Center for
ElectroActive Paper Actuator, Mechanical Engineering Department,
Inha University, 253 Yonghyun-Dong Nam-Ku, 402-751 Incheon, ...

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<http://stacks.iop.org/SMS/18/015003>

The effect of chitosan concentration on the
electrical property of chitosan-blended cellulose
electroactive paper

  
Sang-Dong Jang, et al.

2009 Smart Mater. Struct. 18 015003
(5pp)   doi: 10.1088/0964-1726/18/1/015003 
        
Sang-Dong Jang, Joo-Hyung Kim1, Cai Zhijiang and Jaehwan Kim  
Creative Research Center for EAPap Actuator, Department of
Mechanical Engineering, INHA University, 253 Young-Hyun Dong, Nam
Gu, Incheon 402-751, Korea  
E-mail: joo-hyung.kim@inha.ac.kr  
  
Abstract -- We studied the
effect of chitosan blending on the electrical property of
chitosan-blended cellulose electroactive paper (EAPap) under
different humidity conditions. As the chitosan blending ratio
increased, the real part of the dielectric constant of
chitosan-blended cellulose EAPap increased while the dielectric
loss factor decreased. From the curve fitting of the measured data
using an electrode polarization model, it was found that
increasing the chitosan ratio in the EAPap might promote a
decrease in the relaxation time of the EAPap, resulting in an
increase of the ion mobility and dc conductivity. Over 30% of the
chitosan blending ratio, a gradual increment of the ion mobility
of the EAPap was observed at 40% relative humidity, while a
quadratic increment of the mobility was found at 60% relative
humidity condition. This kind of ion-mobility-enhanced cellulose
EAPap can be used not only for bending actuators but also for
medical applications such as blood clotting patches.

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