Your search keyword '"ionic electroactive polymer"' showing total 13 results

1. Single-Walled Carbon Nanotube-Reinforced PEDOT: PSS Hybrid Electrodes for High-Performance Ionic Electroactive Polymer Actuator.

Author

Tao, Haoxiang, Hu, Guangyao, Lu, Shun, Li, Bing, Zhang, Yongxing, and Ru, Jie

Subjects

*CONDUCTING polymers, *ACTUATORS, *ION-permeable membranes, *NANOTUBES, *ELECTRIC conductivity, *ARTIFICIAL muscles, *PRINTMAKING, *BIONICS

Abstract

Ionic electroactive polymer (iEAP) actuators are recognized as exceptional candidates for artificial muscle development, with significant potential applications in bionic robotics, space exploration, and biomedical fields. Here, we developed a new iEAP actuator utilizing high-purity single-walled carbon nanotubes (SWCNTs)-reinforced poly(3, 4-ethylenedioxythiophene)/poly(4-styrenesulfonate) (PEDOT: PSS, PP) hybrid electrodes and a Nafion/EMIBF4 ion-exchange membrane via a straightforward and efficient spray printing technique. The SWCNT/PP actuator exhibits significantly enhanced electric conductivity (262.9 S/cm) and specific capacitance (22.5 mF/cm2), benefitting from the synergistic effect between SWCNTs and PP. These improvements far surpass those observed in activated carbon aerogel bucky-gel-electrode-based actuators. Furthermore, we evaluated the electroactive behaviors of the SWCNT/PP actuator under alternating square-wave voltages (1–3 V) and frequencies (0.01–100 Hz). The results reveal a substantial bending displacement of 6.44 mm and a high bending strain of 0.61% (at 3 V, 0.1 Hz), along with a long operating stability of up to 10,000 cycles (at 2 V, 1 Hz). This study introduces a straightforward and efficient spray printing technique for the successful preparation of iEAP actuators with superior electrochemical and electromechanical properties as intended, which hold promise as artificial muscles in the field of bionic robotics. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electrical-Modulated Flexible Acoustic Metamaterial: Enhancing Low-Frequency Absorption via an Ionic Electroactive Polymer.

Author

Wang T, Zhang Y, Li B, Hu Y, Aabloo A, and Chang L

Abstract

The growing concern over low-frequency noise pollution resulting from global industrialization has posed substantial challenges in noise attenuation. However, conventional acoustic metamaterials, with fixed geometries, offer limited flexibility in the frequency range adjustment once constructed. This research unveiled the promising potential of ionic electroactive polymers, particularly ionic polymer-metal composites (IPMCs), as a superior candidate to design tunable acoustic metamaterial due to its bidirectional energy conversion capabilities. The previously perceived limitations of the IPMC, including slow reaction and high energy expenditure, owning to its inherent sluggish intermediary ionic mass transport process, were astutely leveraged to expedite the attenuation of low-frequency sound energy. Both our experimental and simulation results elucidated that the IPMC can generate voltage potentials in response to acoustic pressure at frequencies significantly higher than those previously established. In addition, the peak absorption frequency can be effectively shifted by up to 45.7% with the application of a 4 V voltage. By further integration with a microperforated panel (MPP) structure, the developed metamaterial absorbers can achieve complete sound absorption, which was continuously tunable under minimal voltage stimulation across a wide frequency spectrum. In addition, a microslit structure IPMC metamaterial absorber was designed to realize modulation of the perforation rate, and the absorption peak can be shifted by up to 79.2%. These findings signify a pioneering application of ionic intelligent materials and may pave the way for further innovations of tunable low-frequency acoustic structures, ultimately advancing the pragmatic deployment of both soft intelligent materials and acoustic metamaterials.

Published

2024

3. Modeling, fabrication, and characterization of motion platform actuated by carbon polymer soft actuator.

Author

Nakshatharan, S. Sunjai, Johanson, Urmas, Punning, Andres, and Aabloo, Alvo

Subjects

*FABRICATION (Manufacturing), *POLYMERS, *DISPLACEMENT (Mechanics), *ELECTROMECHANICAL devices, *ALGORITHMS

Abstract

Highlights • We proposed ionic polymer actuator based novel parallel manipulation system. • The system can achieve three degrees of freedom. • Electromechanical model is developed and the proposed design is optimized using FEM simulation. • The system can generate linear piston displacement of ±15 mm and rotational motion of ±15 ° around two axes. Abstract Carbon polymer composites (CPC) are kind of soft actuators belonging to the category of ionic electroactive polymer transducers. In this work, we present design, modeling, fabrication, and characterization of a novel parallel manipulation system actuated by the CPC actuators. In this system, four actuators are operated in parallel to manipulate an end effector or a platform to generate motion along the different axis. The major advantage of the current system is that the platform and the actuators are fabricated as a single structure using the simple layer-by-layer spray-deposition method with selective masking. The proposed system is highly dexterous and is capable of generating three degrees of motions, namely, roll, pitch, and piston. The initial structural design and its deformation are optimized by modeling and simulating using finite element method and followed by fabrication and characterization to examine its workspace. The experimental results have demonstrated high levels of manipulability from the CPC actuators that are outstanding in the class of soft ionic actuators while keeping the fabrication method simple, scalable and cost-effective. The proposed configuration has potential application in micromanipulation systems that require large deformation in a confined space. [ABSTRACT FROM AUTHOR]

Published

2018

4. Diseño de un sistema de control electrónico para un dispositivo háptico basado en polímeros electroactivos de nueva generación del tipo iónico

Author

Castellanos Gilabert, Álvaro

Subjects

TECNOLOGIA ELECTRONICA, Haptic device, Polímero electroactivo iónico, Electronic control, Control electrónico, Dispositivo háptico, Ionic electroactive polymer, Grado en Ingeniería Electrónica Industrial y Automática-Grau en Enginyeria Electrònica Industrial i Automàtica

Abstract

[ES] El objeto del TFG es el diseño de un sistema electrónico capaz de excitar un polímero electroactivo en el contexto de un dispositivo háptico (por ejemplo un guante electrónico que trasmite sensaciones táctiles al usuario). Estos polímeros experimentan una deformación mecánica cuando son excitados mediante señales alternas de bajo voltaje (2 V) y frecuencia variable. El TFG estudiará las diferentes alternativas para generar estas señales a partir de un microcontrolador, tales como síntesis digital de señal, convertidor digital-analógico, convertidores de tensión a frecuencia, y amplificadores que excitan los electrodos adheridos a los polímeros. Se propondrá una solución técnica la cual se verificará por simulación., [EN] The object of the TFG is the design of an electronic system capable of exciting an electroactive polymer in the context of a haptic device (e.g. an electronic glove that transmits tactile sensations to the user). These polymers undergo a mechanical deformation when excited by alternating signals of low voltage (2 V) and variable frequency. The TFG will study the different alternatives to generate these signals from a microcontroller, such as digital signal synthesis, digital-to-analog converter, voltage-to-frequency converters, and amplifiers that excite the electrodes attached to the polymers. A technical solution will be proposed and verified by simulation.

Published

2022

5. Impermeable and Compliant: SIBS as a Promising Encapsulant for Ionically Electroactive Devices

Author

Saeedeh Ebrahimi Takalloo, Adelyne Fannir, Giao T. M. Nguyen, Cedric Plesse, Frederic Vidal, and John D.W. Madden

Subjects

encapsulation, conducting polymer, actuator, ionic electroactive polymer, tri-layer, electrolyte, Mechanical engineering and machinery, TJ1-1570

Abstract

Metals and glass are excellent for containing electrolytes and liquids in general, but their rigid mechanics limits their application for mechanically active ionic actuators or flexible/ stretchable electrochemical devices such as batteries and supercapacitors. In this study, we evaluate the performance of spray-coated poly (styrene-block-isobutylene-block-styrene) (SIBS) as a stretchable encapsulant, which suggests that it offers a better combination of compliance and impermeability than any other barrier. We examined the drying time of 360-µm thick encapsulated tri-layer conducting polymer (CP) actuators, comprised of poly(3,4-Ethylenedioxythiophene) (PEDOT) as the CP electrode and an interpenetrated polymer network of polyethylene oxide (PEO) and nitrile butadiene rubber (NBR) as the separator layer, which operates with a 1 M solution of Lithium bis(trifluoromethanesulfonyl)imide (Li+TFSI−) in propylene carbonate (PC). A 100-µm thick SIBS encapsulation layer is anticipated to help these devices to retain 80% of stored PC for more than 1000 times longer compared to when there is no encapsulation (from less than 0.5 days to over 1.5 years). This low permeability combined with the low Young’s modulus of the SIBS film, its biocompatibility, biostability, and FDA approval, as well as ease of fabrication, make this thermoplastic elastomer a promising candidate as an encapsulant for flexible ionic devices such as flexible batteries and supercapacitors, ionic-electrode capacitive sensors, and ionically electroactive actuators. This paves the way for using these devices in implantable and in vivo applications.

Published

2019

6. In situ scanning electron microscopy study of strains of ionic electroactive polymer actuators.

Author

Punning, Andres, Vunder, Veiko, Must, Indrek, Johanson, Urmas, Anbarjafari, Gholamreza, and Aabloo, Alvo

Subjects

ELECTROACTIVE polymer actuators, SCANNING electron microscopy, STRAINS & stresses (Mechanics), IONIC conductivity, DIGITAL image processing

Abstract

We have developed a technique to determine the bending strain of ionic electroactive polymer actuators without the use of the macroscopic bending geometry. In situ comparisons of the scanning electron microscope micrographs from a bending ionic electroactive polymer actuator, using a digital image correction methodology, identify its bi-directional deformation field. The developed technique allows verification of the factual axial and thickness strains of any notional layer of the actuator, including the outer surfaces of the electrodes. Thus, calculation of the bending and thickness strains of the ionic electroactive polymer laminate becomes possible. Moreover, the technique allows the determination of the position of the neutral layer of bending that is an important requirement for the calculation of the second area and bending moments of the beam. The four examples presented demonstrate the potential variations of the bending schemes, in cases where the neutral layer is at the centroid and shifted away from the centroid. [ABSTRACT FROM AUTHOR]

Published

2016

7. Effect of Ionic Polymer Membrane with Multiwalled Carbon Nanotubes on the Mechanical Performance of Ionic Electroactive Polymer Actuators

Author

Minjeong Park, Joo-Hee Kim, Seonpil Kim, and Minhyon Jeon

Subjects

chemistry.chemical_classification, Materials science, blocking force, Polymers and Plastics, Ionic bonding, General Chemistry, Polymer, Carbon nanotube, multiwalled carbon nanotubes, Article, Nafion membrane, law.invention, lcsh:QD241-441, Membrane, lcsh:Organic chemistry, chemistry, law, Electric field, Electroactive polymers, Artificial muscle, Composite material, heat press two-step process, Heat press, ionic electroactive polymer

Abstract

Ionic electroactive polymer (IEAP) actuators have received interest because of their advantageous properties, including their large displacement, high energy density, light weight, and low power consumption under a low electric field. However, they have a low blocking force under driving, and it is difficult to control the thickness of the ionic polymer membrane. In this study, an IEAP actuator is fabricated using a Nafion membrane with added multiwalled carbon nanotubes to increase the blocking force. A heat press two-step process is also developed to produce a constant and uniform membrane. The fabricated Nafion membrane with 0.2 wt% multiwalled carbon nanotubes has the largest displacement and highest blocking force. As a result, the developed heat press two-step method can be used in various polymer-casting fields, and the fabricated carbon nanotube-based IEAP actuators can serve as useful references in fields such as flexible robotics and artificial muscles.

Published

2020

8. Impermeable and Compliant: SIBS as a Promising Encapsulant for Ionically Electroactive Devices

Author

Giao T. M. Nguyen, Saeedeh Ebrahimi Takalloo, Frédéric Vidal, John D. W. Madden, Adelyne Fannir, Cédric Plesse, Laboratoire de Physico-chimie des Polymères et des Interfaces (LPPI), Fédération INSTITUT DES MATÉRIAUX DE CERGY-PONTOISE (I-MAT), CY Cergy Paris Université (CY)-CY Cergy Paris Université (CY), Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine, CY Cergy Paris Université (CY), and Université Paris-Seine

Subjects

Control and Optimization, Fabrication, Materials science, Biocompatibility, lcsh:Mechanical engineering and machinery, 02 engineering and technology, Electrolyte, electrolyte, 010402 general chemistry, 01 natural sciences, [SPI.MAT]Engineering Sciences [physics]/Materials, chemistry.chemical_compound, PEDOT:PSS, Artificial Intelligence, tri-layer, lcsh:TJ1-1570, conducting polymer, Composite material, Thermoplastic elastomer, actuator, ionic electroactive polymer, Conductive polymer, Supercapacitor, Mechanical Engineering, [CHIM.MATE]Chemical Sciences/Material chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, [CHIM.POLY]Chemical Sciences/Polymers, chemistry, Propylene carbonate, encapsulation, 0210 nano-technology

Abstract

Metals and glass are excellent for containing electrolytes and liquids in general, but their rigid mechanics limits their application for mechanically active ionic actuators or flexible/ stretchable electrochemical devices such as batteries and supercapacitors. In this study, we evaluate the performance of spray-coated poly (styrene-block-isobutylene-block-styrene) (SIBS) as a stretchable encapsulant, which suggests that it offers a better combination of compliance and impermeability than any other barrier. We examined the drying time of 360-&micro, m thick encapsulated tri-layer conducting polymer (CP) actuators, comprised of poly(3,4-Ethylenedioxythiophene) (PEDOT) as the CP electrode and an interpenetrated polymer network of polyethylene oxide (PEO) and nitrile butadiene rubber (NBR) as the separator layer, which operates with a 1 M solution of Lithium bis(trifluoromethanesulfonyl)imide (Li+TFSI&minus, ) in propylene carbonate (PC). A 100-&micro, m thick SIBS encapsulation layer is anticipated to help these devices to retain 80% of stored PC for more than 1000 times longer compared to when there is no encapsulation (from less than 0.5 days to over 1.5 years). This low permeability combined with the low Young&rsquo, s modulus of the SIBS film, its biocompatibility, biostability, and FDA approval, as well as ease of fabrication, make this thermoplastic elastomer a promising candidate as an encapsulant for flexible ionic devices such as flexible batteries and supercapacitors, ionic-electrode capacitive sensors, and ionically electroactive actuators. This paves the way for using these devices in implantable and in vivo applications.

Published

2019

9. Enhanced Stability and Driving Performance of GO–Ag-NW-based Ionic Electroactive Polymer Actuators with Triton X-100-PEDOT:PSS Nanofibrils

Author

Seokju Yoo, Seonpil Kim, Yunkyeong Bae, Minhyon Jeon, and Minjeong Park

Subjects

Materials science, Polymers and Plastics, Composite number, engineering.material, Article, law.invention, lcsh:QD241-441, chemistry.chemical_compound, 4-(1,1,3,3-Tetramethylbutyl)phenyl-polyethylene glycol, lcsh:Organic chemistry, Coating, PEDOT:PSS, law, Electroactive polymers, ionic electroactive polymer, Graphene, General Chemistry, silver nanowires, Chemical engineering, chemistry, Electrode, Triton X-100, engineering, graphene oxide, poly(3,4-ethylenedioxythiophene)–poly(styrenesulfonate) (PEDOT:PSS), Layer (electronics)

Abstract

Ionic electroactive polymers (IEAPs) have received considerable attention for their flexibility, lightweight composition, large displacement, and low-voltage activation. Recently, many metal&ndash, nonmetal composite electrodes have been actively studied. Specifically, graphene oxide&ndash, silver nanowire (GO&ndash, Ag NW) composite electrodes offer advantages among IEAPs with metal&ndash, nonmetal composite electrodes. However, GO&ndash, Ag NW composite electrodes still show a decrease in displacement owing to low stability and durability during driving. Therefore, the durability and stability of the IEAPs with metal&ndash, nonmetal composite electrodes must be improved. One way to improve the device durability is coating the electrode surface with a protective layer. This layer must have enough flexibility and suitable electrical properties such that it does not hinder the IEAPs&rsquo, driving. Herein, a poly(3,4-ethylenedioxythiophene)&ndash, poly(styrenesulfonate) (PEDOT:PSS) protective layer and 4-(1,1,3,3-tetramethylbutyl)phenyl-polyethylene glycol (Triton X-100) are applied to improve driving performance. Triton X-100 is a nonionic surfactant that transforms the PEDOT:PSS capsule into a nanofibril structure. In this study, a mixed Triton X-100/PEDOT:PSS protective layer at an optimum weight ratio was coated onto the GO&ndash, Ag NW composite-electrode-based IEAPs under various conditions. The IEAP actuators based on GO&ndash, Ag NW composite electrodes with a protective layer of PEDOT:PSS treated with Triton X-100 showed the best stability and durability.

Published

2019

10. Effect of Ionic Polymer Membrane with Multiwalled Carbon Nanotubes on the Mechanical Performance of Ionic Electroactive Polymer Actuators.

Author

Kim, Joohee, Park, Minjeong, Kim, Seonpil, and Jeon, Minhyon

Subjects

*CONDUCTING polymers, *ARTIFICIAL muscles, *POLYMERIC membranes, *MULTIWALLED carbon nanotubes, *ACTUATORS, *ELECTRIC fields, *NAFION

Abstract

Ionic electroactive polymer (IEAP) actuators have received interest because of their advantageous properties, including their large displacement, high energy density, light weight, and low power consumption under a low electric field. However, they have a low blocking force under driving, and it is difficult to control the thickness of the ionic polymer membrane. In this study, an IEAP actuator is fabricated using a Nafion membrane with added multiwalled carbon nanotubes to increase the blocking force. A heat press two-step process is also developed to produce a constant and uniform membrane. The fabricated Nafion membrane with 0.2 wt% multiwalled carbon nanotubes has the largest displacement and highest blocking force. As a result, the developed heat press two-step method can be used in various polymer-casting fields, and the fabricated carbon nanotube-based IEAP actuators can serve as useful references in fields such as flexible robotics and artificial muscles. [ABSTRACT FROM AUTHOR]

Published

2020

11. Impermeable and Compliant: SIBS as a Promising Encapsulant for Ionically Electroactive Devices.

Author

Ebrahimi Takalloo, Saeedeh, Fannir, Adelyne, Nguyen, Giao T. M., Plesse, Cedric, Vidal, Frederic, and Madden, John D. W.

Subjects

ELASTOMERS, CONDUCTING polymers, POLYETHYLENE oxide, YOUNG'S modulus, THERMOPLASTIC elastomers, CAPACITIVE sensors, STYRENE

Abstract

Metals and glass are excellent for containing electrolytes and liquids in general, but their rigid mechanics limits their application for mechanically active ionic actuators or flexible/ stretchable electrochemical devices such as batteries and supercapacitors. In this study, we evaluate the performance of spray-coated poly (styrene-block-isobutylene-block-styrene) (SIBS) as a stretchable encapsulant, which suggests that it offers a better combination of compliance and impermeability than any other barrier. We examined the drying time of 360-µm thick encapsulated tri-layer conducting polymer (CP) actuators, comprised of poly(3,4-Ethylenedioxythiophene) (PEDOT) as the CP electrode and an interpenetrated polymer network of polyethylene oxide (PEO) and nitrile butadiene rubber (NBR) as the separator layer, which operates with a 1 M solution of Lithium bis(trifluoromethanesulfonyl)imide (Li+TFSI−) in propylene carbonate (PC). A 100-µm thick SIBS encapsulation layer is anticipated to help these devices to retain 80% of stored PC for more than 1000 times longer compared to when there is no encapsulation (from less than 0.5 days to over 1.5 years). This low permeability combined with the low Young's modulus of the SIBS film, its biocompatibility, biostability, and FDA approval, as well as ease of fabrication, make this thermoplastic elastomer a promising candidate as an encapsulant for flexible ionic devices such as flexible batteries and supercapacitors, ionic-electrode capacitive sensors, and ionically electroactive actuators. This paves the way for using these devices in implantable and in vivo applications. [ABSTRACT FROM AUTHOR]

Published

2019

12. Enhanced Stability and Driving Performance of GO–Ag-NW-based Ionic Electroactive Polymer Actuators with Triton X-100-PEDOT:PSS Nanofibrils.

Author

Park, Minjeong, Yoo, Seokju, Bae, Yunkyeong, Kim, Seonpil, and Jeon, Minhyon

Subjects

*CONDUCTING polymers, *ELECTROACTIVE substances, *TRITON X-100, *NONIONIC surfactants, *ACTUATORS, *ETHYLENE glycol

Abstract

Ionic electroactive polymers (IEAPs) have received considerable attention for their flexibility, lightweight composition, large displacement, and low-voltage activation. Recently, many metal–nonmetal composite electrodes have been actively studied. Specifically, graphene oxide–silver nanowire (GO–Ag NW) composite electrodes offer advantages among IEAPs with metal–nonmetal composite electrodes. However, GO–Ag NW composite electrodes still show a decrease in displacement owing to low stability and durability during driving. Therefore, the durability and stability of the IEAPs with metal–nonmetal composite electrodes must be improved. One way to improve the device durability is coating the electrode surface with a protective layer. This layer must have enough flexibility and suitable electrical properties such that it does not hinder the IEAPs' driving. Herein, a poly(3,4-ethylenedioxythiophene)–poly(styrenesulfonate) (PEDOT:PSS) protective layer and 4-(1,1,3,3-tetramethylbutyl)phenyl-polyethylene glycol (Triton X-100) are applied to improve driving performance. Triton X-100 is a nonionic surfactant that transforms the PEDOT:PSS capsule into a nanofibril structure. In this study, a mixed Triton X-100/PEDOT:PSS protective layer at an optimum weight ratio was coated onto the GO–Ag NW composite-electrode-based IEAPs under various conditions. The IEAP actuators based on GO–Ag NW composite electrodes with a protective layer of PEDOT:PSS treated with Triton X-100 showed the best stability and durability. [ABSTRACT FROM AUTHOR]

Published

2019

13. Linear Artificial Muscle Based on Ionic Electroactive Polymer: A Rational Design for Open‐Air and Vacuum Actuation.

Author

Fannir, Adelyne, Temmer, Rauno, Nguyen, Giao T. M., Cadiergues, Laurent, Laurent, Elisabeth, Madden, John D. W., Vidal, Frederic, and Plesse, Cedric

Subjects

*ARTIFICIAL muscles, *CONDUCTING polymers, *VACUUM, *LINEAR polymers, *ELECTROACTIVE substances, *ACTUATORS

Abstract

The development of linear muscle‐like actuators remains a key objective in the field of electroactive polymers (EAPs). While ionic EAPs are promising technologies to develop biomimetic artificial muscles, their reliance on liquid electrolytes for operation typically restricts them to use in bending devices. Seldom have ionic linear actuators been demonstrated in air, and never in vacuum. Here both are demonstrated. A rational approach supported by a theoretical model is described to identify the general conditions allowing the design of ionic actuators with intrinsically linear deformations. The model highlights that linear deformation can occur by combining two electroactive electrodes with different mechanical and/or electromechanical properties. Where previous work on laminated actuators resulted in bending only, here it is shown that by combining one soft and one stiff electrode, or one highly expanding electrode, and the other minimally deforming electrode, 0.55% linear strain is achieved when activated with 2 V. Best combination of electrodes is selected based on electromechanical model predictions. Single actuator fibers are fabricated for experimental validation. Graded force up to 0.18 N has been achieved by bundling together five linear actuators. The resulting artificial muscles operate in open‐air, and also under high vacuum conditions, opening possibilities for space applications. A linear polymer actuator operating in air and in vacuum mimics muscle in its ability to scale forces using recruitment of parallel fibers. In this new approach, a rational design of linear artificial muscles supported by electromechanical model is described for ionic electroactive polymers. Artificial muscle bundles are developed and operated in open‐air but also under high vacuum conditions. [ABSTRACT FROM AUTHOR]

Published

2019