Electroactive polymers

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File:EAP-example2.png
Figure 1: Cartoon drawing of an EAP gripping device. (a) A voltage is applied and the EAP fingers deform in order to surround the ball. (b) When the voltage is removed the EAP fingers return to their original shape and grip the ball. (c)
Electroactive Polymers, or EAPs, are polymers that exhibits a change in size or shape when stimulated by an electric field. The most common applications of this type of material are in actuators and sensors. A typical characteristic property of an EAP is that they will undergo a large amount of deformation while sustaining large forces. The majority of historic actuators are made of ceramic piezoelectric materials. While these materials are able to withstand large forces, they commonly will only deform a fraction of a percent. In the late 1990s, it has been demonstrated that some EAPs can exhibit up to a 380% strain [1], which is much more than any ceramic actuator. Another one of the most common applications for EAPs is in the field of robotics in the development of artificial muscles. Due to this being one of the most common and attractive applications, EAPs are often referred to as artificial muscles. A cartoon drawing of a gripping device using EAPs as "fingers" to grip a ball is depicted in Figure 1.

History of EAPs

The field of EAPs emerged back in 1880, when Wilhelm Roentgen designed an experiment in which he tested the effect of an electrical current on the mechanical properties of a rubber band[2]. The rubber band was fixed at one end and was attached to a mass at the other. It was then charged and discharged to study the change in length with electrical current. Sacerdote followed up on Roentgen’s experiment by formulating a theory on strain response to an applied electric field in 1899[2]. It wasn’t until the year 1925 that the first piezoelectric polymer was discovered (Electret). Electret was formed by combining carnauba wax, rosin and beeswax, and then cooling the solution while it is subject to an applied DC electrical bias. The mixture would then solidify into a polymeric material that exhibited a piezoelectric effect.

Polymers that respond to environmental conditions other than an applied electrical current have also been a large part of this area of study. In 1949, Katchalsky et. al. demonstrated that when collagen filaments are dipped in acid or alkali solutions they would respond with a change in volume[2]. The collagen filaments were found to expand in an acidic solution and contract in an alkali solution. Although other stimuli (such as pH) have been investigated, due to its ease and practicality most research has been devoted to developing polymers that respond to electrical stimuli in order to mimic biological systems.

It wasn’t until the late 1960s when the next major breakthrough in EAPs was observed. In 1969, Kawai was able to demonstrate that polyvinylidene fluoride (PVDF) exhibits a large piezoelectric effect[2]. This sparked research interest in developing other polymers systems that would show a similar effect. In 1977, the first electrically conducting polymers were discovered by Hideki Shirakawa et.al [3]. Shirakawa along with Alan MacDiarmid and Alan Heeger demonstrated that polyacetylene was electrically conductive, and that by doping it with iodine vapor, they could enhance its conductivity by 8 orders of magnitude. Thus the conductance was close to that of a metal. By the late 1980s a number of other polymers had been shown to exhibit a piezoelectric effect or were demonstrated to be conductive.

In the early 1990s, ionic polymer-metal composites were developed and shown to exhibit electroactive properties far superior to previous EAPs. The major advantage of IPMCs was that they were able to show activation (deformation) at voltages as low as 1 or 2 volts[2]. This is orders of magnitude less than any previous EAP. Not only was the activation energy for these materials much lower, but they could also undergo much larger deformations. IMPCs were shown to exhibit anywhere up to 380% strain, orders of magnitude larger than previously developed EAPs[1]. In 1999, one of the pioneers of the field of robotics and artificial muscles, Yoseph Bar-Cohen, proposed the Armwrestling Match of EAP Robotic Arm Against Human Challenge[2]. This was a challenge in which research groups around the world competed to design a robotic arm consisting of EAP muscles that could defeat a human in an arm wrestling match. The first challenge was held at the Electroactive Polymer Actuators and Devices Conference in 2005[2]. Another major milestone of the field is that the first commercially developed device including EAPs as an artificial muscle was produced in 2002 by Eamex in Japan[1]. This device was a fish that is able to swim on its own, moving its tail using an EAP muscle. But the progress in practical development is not satisfactory, probably due to misleading in fundamental research [4].

Types of Electroactive Polymers

EAP can have several configurations, but are generally divided in two principal classes: Dielectric and Ionic.

Dielectric EAPs

  • Dielectric EAPs, are materials in which actuation is caused by electrostatic forces between two electrodes which squeeze the polymer. Dielectric elastomers are capable of very high strains and are fundamentally a capacitor that changes its capacitance when a voltage is applied by allowing the polymer to compress in thickness and expand in area due to the electric field. This type of EAP typically requires a large actuation voltage to produce high electric fields (hundreds to thousands of volts), but very low electrical power consumption. Dielectric EAPs require no power to keep the actuator at a given position. Examples are electrostrictive polymers and dielectric elastomers.

Ferroelectric Polymers

Ferroelectric Polymers[5][6] are a group of crystalline polar polymers that are also ferroelectric, meaning that they maintain a permanent electric polarization that can be reversed, or switched, in an external electric field. Ferroelectric polymers, such as polyvinylidene fluoride(PVDF), are used in acoustic transducers and electromechanical actuators because of their inherent piezoelectric response, and as heat sensors because of their inherent pyroelectric response[7].

File:Polyvinylidene fluoride.png
Figure 1: Structure of Poly(vinylidene fluoride)
Electrostrictive Graft Polymers
File:Electrostrictive Graft PolymerII.PNG
Figure 2: Cartoon of an electrostrictive graft polymer.

Electrostricive graft polymers consist of flexible backbone chains with branching side chains. The side chains on neighboring backbone polymers cross link and form crystal units. The backbone and side chain crystal units can then form polarized monomers, which contain atoms with partial charges and generate dipole moments, shown in Figure 2[8]. When an electrical field is applied, a force is applied to each partial charge and causes rotation of the whole polymer unit. This rotation causes electrostrictive strain and deformation of the polymer.

Liquid Crystalline Polymers

Main-chain liquid crystalline polymers have mesogenic groups linked to each other by a flexible spacer. The mesogens within a backbone form the mesophase structure causing the polymer itself to adopt a conformation compatible with the structure of the mesophase. The direct coupling of the liquid crystalline order with the polymer conformation has given main-chain liquid crystalline elastomers a large amount of interest[9]. The synthesis of highly oriented elastomers leads to have a large strain thermal actuation along the polymer chain direction with temperature variation resulting in unique mechanical properties and potential applications as mechanical actuators.

Ionic EAPs

  • Ionic EAPs, in which actuation is caused by the displacement of ions inside the polymer. Only a few volts are needed for actuation, but the ionic flow implies a higher electrical power needed for actuation, and energy is needed to keep the actuator at a given position. Examples of ionic EAPS are conductive polymers, ionic polymer-metal composites (IPMCs), and responsive gels. Yet another example is a Bucky gel actuator, which is a polymer-supported layer of polyelectrolyte material consisting of an ionic liquid sandwiched between two electrode layers consisting of a gel of ionic liquid containing single-wall carbon nanotubes [10]. As the name implies, these gel actuators can also be made with bucky balls instead of nanotubes[11].
Electrorheological Fluid

Main Article: Electrorheological Fluid

File:EAP-composite.png
Figure 3: The cations in the ionic polymer-metal composite are randomly oriented in the absence of an electric field. Once a field is applied the cations gather to the side of the polymer in contact with the anode causing the polymer to bend.

Electrorheological fluids change the viscosity of a solution with the application of an electric field. The fluid is a suspension of polymers in a low dielectric-constant liquid[12]. With the application of a large electric field the viscosity of the suspension increases. Potential applications of these fluids include shock absorbers, engine mounts and acoustic dampers[12].

Ionic polymer-metal composite

Ionic polymer-metal composites consist of a thin ionomeric membrane with noble metal electrodes plated on its surface. It also has cations to balance the charge of the anions fixed to the polymer backbone[13]. They are very active actuators that show very high deformation at low applied voltage and show low impedance. Ionic polymer-metal composites work through electrostatic attraction between the cationic counter ions and the anode of the applied electric field, a schematic representation is shown in Figure 3. These types of polymers show the greatest promise for bio-mimetic uses as collagen fibers are essentially composed of natural charged ionic polymers[14]. Nafion and Flemion are commonly used ionic polymer metal composites[15].

Comparison of Electronic and Ionic EAPs

Dielectronic polymers are able to hold their induced displacement while activated under a DC voltage[16]. This allows dielectronic polymers to be considered for robotic applications. These types of materials also have high mechanical energy density and can be operated in air without a major decrease in performance. However, dielectronic polymers require very high activation fields (>10v/um) that are close to the breakdown level.

The activation of ionic polymers, on the other hand, requires only 1-2 volts. They however need to maintain wetness, though some polymers have been developed as self contained encapsulated activators which allows their use in dry environments[14]. Ionic polymers also have a low electromechanical coupling. They are however ideal for the bio-mimetic devices.

Characterization

While there are many different ways electroactive polymers can be characterized, only three will be addressed here: stress-strain curve, dynamic mechanical thermal analysis, and dielectric thermal analysis.

Stress-Strain Curve

Main article: Stress-strain curve

File:LCpolymersII.png
Figure 4: The unstressed polymer spontaneously forms a folded structure, upon application of a stress the polymer regains its original length.

Stress strain curves provide information about the polymer’s mechanical properties such as the brittleness, elasticity and yield strength of the polymer. This is done by providing a force to the polymer at a uniform rate and measuring the deformation that results[17]. An example of this deformation is shown in Figure 4. This technique is useful for determining the type of material (brittle, tough, etc.), but it is a destructive technique as the stress is increased until the polymer fractures.

Dynamic mechanical thermal analysis (DMTA)

Main article: Dynamic mechanical analysis

Both dynamic mechanical analysis is a non destructive technique that is useful in understanding the mechanism of deformation at a molecular level. In DMTA a sinusoidal stress is applied to the polymer, and based on the polymer’s deformation the elastic modulus and damping characteristics are obtained (assuming the polymer is a damped harmonic oscillator)[17]. Elastic materials take the mechanical energy of the stress and convert it into potential energy which can later be recovered. An ideal spring will use all the potential energy to regain its original shape (no dampening), while a liquid will use all the potential energy to flow, never returning to its original position or shape (high dampening). A viscoeleastic polymer will exhibit a combination of both types of behavior[17].

Dielectric thermal analysis (DETA)

Main article: Dielectric thermal analysis

DETA is similar to DMTA, but instead of an alternating mechanical force an alternating electric field is applied. The applied field can lead to polarization of the sample, and if the polymer contains groups that have permanent dipoles (as in Figure 2), they will align with the electrical field[17]. The permittivity can be measured from the change in amplitude and resolved into dielectric storage and loss components. The electric displacement field can also be measured by following the current[17]. Once the field is removed, the dipoles will relax back into a random orientation.

Applications of EAP

File:Artificial Muscle.png
Figure 5: Cartoon drawing of an arm controlled by EAPs. When a voltage is applied (blue muscles) the polymer expands. When the voltage is removed (red muscles) the polymer returns to its original state.
EAP materials can be easily manufactured into various shapes due to the ease in processing many polymeric materials, making them very versatile materials. One potential application for EAPs is that they can potentially be integrated into microelectromechanical systems (MEMS) to produce smart actuators. As the most prospective practical research direction, EAPs have been utilized in artificial muscles[18]. Their ability to emulate the operation of biological muscles with high fracture toughness, large actuation strain and inherent vibration damping draw the attention of scientists in this field[2].

In recent years, “electro active polymers for refreshable Braille displays”[19] has emerged to aid the visually impaired in fast reading and computer assisted communication. This concept is based on using an EAP actuator configured in an array form. Rows of electrodes on one side of an EAP film and columns on the other activate individual elements in the array. Each element is mounted with a Braille dot and is lowered by applying a voltage across the thickness of the selected element, causing local thickness reduction. Under computer control, dots would be activated to create tactile patterns of highs and lows representing the information to be read.

Small pumps can also be achieved by applying EAP materials. These pumps could be used for drug delivery, microfluidic devices, active flow control, and a multitude of consumer applications. The most likely configuration for a pump based on actuators would be a dual diaphragm device. The advantages that an ionomeric pump could offer would be low voltage (battery) operation, extremely low noise signature, high system efficiency, and highly accurate control of flow rate[20].

Another technology that can benefit from the unique properties of EAP actuators is optical membranes. Due to their low modulus, the mechanical impedance of the actuators, they are well-matched to common optical membrane materials. Also, a single EAP actuator is capable of generating displacements that range from microns to centimeters. For this reason, these materials can be used for static shape correction and jitter suppression. These actuators could also be used to correct for optical aberrations due to atmospheric interference[21].

Since these materials exhibit excellent electroactive character, EAP materials show potential in biomimetic-robot research, stress sensors and acoustics field, which will make EAPs become a more attractive study topic in the near future. They have been used for various actuators such as face muscles and arm muscles in humanoid robots.[22]

Future Directions

The field of EAPs is far from mature, which leaves several issues that still need to be worked on[2]. The performance and long-term stability of the EAP should be improved by designing a water impermeable surface. This will prevent the evaporation of water contained in the EAP, and also reduce the potential loss of the positive counter ions when the EAP is operating submerged in an aqueous environment. Improved surface conductivity should be explored using methods to produce a defect-free conductive surface. This could possibly be done using metal vapor deposition or other doping methods. It may also be possible to utilize conductive polymers to form a thick conductive layer. Heat resistant EAP would be desirable to allow operation at higher voltages without damaging the internal structure of the EAP due to the generation of heat in the EAP composite. Development of EAPs in different configurations (e.g., fibers and fiber bundles), would also be beneficial, in order to increase the range of possible modes of motion.

See also

References

  1. 1.0 1.1 1.2 "Bar-Cohen, Yoseph "Artificial Muscles using Electroactive Polymers (EAP): Capabilities, Challenges and Potential" (PDF). 
  2. 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 "Electrochemistry Encyclopedia: Electroactive Polymers (EAP)". 
  3. Finkenstadt,Victoria L. (2005). Appl Microbiol Biotechnol. 67: 735–745.  Missing or empty |title= (help)doi:10.1007/s00253-005-1931-4
  4. Ali Eftekhari (2010). Chemistry of Materials. 22: 2689.  Missing or empty |title= (help)doi:10.1021/cm903343t
  5. "Ferroelectric Properties of Vinylidene Fluoride Copolymers," by T. Furukawa, in Phase Transitions, Vol. 18, pp. 143-211 (1989).
  6. Nalwa, H. (1995). Ferroelectric Polymers (First ed.). New York: Marcel Dekker, INC. ISBN 0-8247-9468-0. 
  7. Lovinger, A.J. (1983). Science. 220: 1115–1121.  Missing or empty |title= (help)
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  10. Qu, L., Peng, Q., Dai, L., Spinks, G.M., Wallace, G.G., Baughman, R.H. (2008). MRS Bulletin. 33: 215–224.  Missing or empty |title= (help)ISSN 0883-7694
  11. Fully Plastic Actuator through Layer-by-Layer Casting with Ionic-Liquid-Based Bucky Gel Takanori Fukushima, Kinji Asaka, Atsuko Kosaka, Takuzo Aida p. Angewandte Chemie International Edition Volume 44, Issue 16 2410 2005
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  15. Park, I.S., Jung, K., Kim, D., Kim, S.M, Kim, K.J. (2008). MRS Bulletin. 33: 190–195.  Missing or empty |title= (help)ISSN 0883-7694
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  19. Bar-Cohen, Yoseph (11 September 2009). "Electroactive polymers for refreshable Braille displays". SPIE. 
  20. "Electroactive Polymer Pumps". Discover technologies Inc. 7 June 2009. 
  21. "Adaptive Membrane Optics". Discover technologies Inc. 7 June 2009. 
  22. http://eap.jpl.nasa.gov/ NASA WorldWide Electroactive Polymer Actuators Webhub

External links

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