Electroactive Polymers and Coatings

Toit, Lisa C. du; Kumar, Pradeep; Choonara, Yahya E.; Pillay, Viness

doi:10.1007/978-3-319-26893-4_3

Cited by 3 publications

(3 citation statements)

References 179 publications

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“…The ease and flexibility of synthesizing polypyrrole in mass at ambient temperature in many solvents, including water is the reason for its availability [35][36][37][38]. equipment, computer displays, biosensors, blood conduits, drug delivery system, neural probes, and as a biological material in neural tissue engineering [43][44][45][46][47].…”

Section: Polypyrrolementioning

confidence: 99%

Advancement in the Production and Applications of Conductive Polymers (CPs)

Akande

Ajayi

Fajobi

et al. 2021

KEM

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Conductive polymers are a class of engineering materials which possess remarkably reversible redox property and atypical combination of characteristics of plastics and metals. The potential usefulness of conductive polymers has grown exceedingly in the technological field such as telecommunication, electronics, storage systems and protective devices. The prospective of conductive polymers has further deepened the interest of researchers for their applications in several areas. Some of the popular types of conductive polymers are polythiophene, polyindole, polyacetylene, polypyrrole, polyphenyl vinylene, polyaniline, Poly (3,4ethylenedioxythiophene), which are produced via redox and chemical (CM) or electrochemical (ECM) oxidation processes. Polymers are doped to introduce charge carriers known as polarons and bipolarons into them, to make them conductive. Conductive polymers have limitations such as a poor mechanical characteristic or poor flexibility, low process-ability and poor biocompatibility, which have made researchers investigate different chemical modification methods. Conductive polymers have potential applications in the field of supercapacitors, solar cells, biosensors, chemical sensors and actuators, tissue engineering, e.t.c. This article has attempted to provide an up to date review on different aspects of conductive polymers such as production, doping, applications and conductivity of selected conductive polymers.

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Section: Polypyrrolementioning

confidence: 99%

Advancement in the Production and Applications of Conductive Polymers (CPs)

Akande

Ajayi

Fajobi

et al. 2021

KEM

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“…Advancement of effective and powerful mechanisms and devices that are actuated by EAP materials needs enhanced understanding of their behaviour, design concepts for efficient actuation, generation and sensing and reliable and repeatable fabrication and characterization methods, as well as effective control algorithms and electronics (Bar-Cohen, 2017; Bundhoo, 2009; Kaasik et al, 2017; Mengmeng et al, 2017; Rus and Tolley, 2015; Wang et al, 2016; Wilson et al, 2007). The current accomplishments and challenges in the field of EAP are noteworthy (Asaka and Nakamura, 2014; Biggs et al, 2013; du Toit et al, 2016; Vinogradov et al, 2005). Kaneto (2016) has shown that the research trends of EAPs and conducting polymers characteristics as given in Table 4.…”

Section: Recent Trends and Advancementmentioning

confidence: 99%

“…Advancement of effective and powerful mechanisms and devices that are actuated by EAP materials needs enhanced understanding of their behaviour, design concepts for efficient actuation, generation and sensing and current accomplishments and challenges in the field of EAP are noteworthy (Asaka and Nakamura, 2014;Biggs et al, 2013;du Toit et al, 2016;Vinogradov et al, 2005). Kaneto (2016) has shown that the research trends of EAPs and conducting polymers characteristics as given in Table 4.…”

Section: Recent Trends and Advancementmentioning

confidence: 99%

A review on electroactive polymers development for aerospace applications

Bashir

Rajendran

2018

Journal of Intelligent Material Systems and Structures

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Newfangled smart materials have inspired the researchers to look for more efficient materials that can respond to specific stimuli and retain the original shape. Electroactive polymers are such materials which are capable of sensing and real-time actuation. Various electroactive polymers are excellent candidates due to high strain rate, fast response, reliability and high mechanical compliance despite tough manufacturing. In this study, electroactive polymers are reviewed and the general enabling mechanisms employing their distinct characteristics are presented, and the factors influencing the properties of various electroactive polymers are also discussed. Our study also enumerates the current trends in the development of electroactive polymers along with its progress in aerospace discipline. The electromechanical properties of electroactive polymer materials endow them the capability to work as both sensors and actuators in the field of aerospace. Hence, we provide an overview of various applications of electroactive polymers in aerospace field, notably aircraft morphing. These actuators are vastly used in aerospace applications like Mars Nano-rover, space robotic, flapping wings and active flap. Therefore, the electroactive polymer applications such as effective actuators can be investigated more in their materials, molecular interactions, electromechanics and actuation mechanisms. Considering electroactive polymers unique properties, they will endeavour the great potential applications within aerospace industry.

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