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Authors: Indrek Must Geoffrey M Spinks Alvo Aabloo
Publish Date: 2016
Volume: , Issue: , Pages: 1-16
Abstract
Carbon is a distinctive electrode material for actuators as it is available in a wide variety of forms ranging from monoliths to powders fibers and yarns The diversity in the properties of different carbonaceous materials is also expressed in a variety of actuation mechanisms This chapter considers two classes of actuators – electrochemically and electrothermally driven actuators – which both make use of carbonaceous materials as active elements In both of the listed types of actuators carbon is especially advantageous because of its chemical and thermal inertness and also because of its high intrinsic electrical conductivity The working principles of different actuators having carbonaceous electrodes are drastically different and so are the optimization criteria for selecting a particular type of carbon for a particular type of actuator This chapter is to explain some important practical considerations for successful experimentation with the carbonbased actuators Special attention is bestowed on the choice of materials and the choice of appropriate electrical driving signal The effects caused by the ambient environment are discussed Finally a selection of commonly used characterization methods is suggestedWhen starting experimentation with any type of actuator their particularly distinctive characteristics and possible multifunctional nature should be considered as they can be essential in consideration of possible applications and characterization methods for the particular types of actuatorsIn the electrothermally driven actuators synergistic effect between a carbon filament as the host material and a polymeric filler having large thermal expansion coefficient is achieved These systems have only recently been described Lima et al 2012 and are based on electrochemically driven carbon nanotube yarn torsional actuators Foroughi et al 2011 The electrothermal systems also utilize carbon nanotube yarns but incorporate a guest material as filler Electric heating causes guest volume expansion that then produces a combination of yarn torsion and lengthwise contractionWhereas electrothermally driven actuators although more straightforward in their construction have gained their popularity primarily during the past few years’ time the electrochemically driven actuators having carbonaceous electrodes have been first proposed in 1999 Baughman et al 1999 The working principle of the electrochemically driven actuators involves many concurrent mechanisms the ratio of which is still under dispute to date It is generally accepted that the strain difference between the oppositely charged electrodes is related to the shift in the local concentration of the electrolyte ions that accompanies with the buildup of electric doublelayer Kosidlo et al 2013The introduction of carbonaceous electrode materials for the electrochemically driven actuators intersected two classes of electrochemical devices that were considered as being separate beforehand – the electromechanical actuators and the electric doublelayer capacitors also known as supercapacitors Although the conventional supercapacitors and the “conventional” electrochemically driven actuators have notable differences in their particular optimization parameters their governing physical processes are virtually identicalThe similarity between the carbonaceous electrochemically driven actuators and the supercapacitors is particularly noteworthy Among the wide range of existing types of “smart” actuators whose working principle involves electroosmosis of ions in the extent of a layered microporous laminate the actuators with carbonaceous electrodes resemble the most to the supercapacitors The high level of similarity is anticipated as identical carbonaceous materials can be used in construction of either of the two devices – a supercapacitor Simon et al 2013 or an actuator Kosidlo et al 2013 After the introduction of carbon as the superior active material for the electrochemically activated actuators in 1999 the emerged types of actuators resembled to a great extent to the supercapacitors which had been in commercial production for many decades already – since 1978 Miller 2007 It has been demonstrated that a the electrochemically driven actuators have a decent energystorage capability Torop et al 2009 2011 and b opportune employment of the capacitive nature of the electrochemically driven actuators gives completely new functionalities to these laminates originally intended for use as actuators Must et al 2013 In order to emphasize the capacitive nature of the electrochemically driven actuators “actuating” and “charging” of this type of actuators are used as synonyms in this chapterThe capacitive nature of the electrochemically driven actuators with carbonaceous electrodes is of particular importance to consider when starting experimentation with this type of actuators – the capacitive properties of the actuators determine the most suitable driving waveform and characterization methodsThe electrothermally driven actuators benefit the most from carbons that have directional nanostructures resulting in high mechanical yield strength but also in sufficient electrical conductivity along the nanostructure direction Twisted yarns of multiwalled carbon nanotubes are the most extensively studied of these relatively new actuator materials Twisting the multiwalled CNTs adds considerable strength Zhang et al 2004 but the method of preparation also allows the ready addition of guest materials incorporated within the continuously twisted CNT bundles Lima et al 2011 Electrothermally activated hybrid CNT yarns have been produced by infiltrating twisted CNT yarns with molten paraffin wax The yarns were prepared by drawing from a “forest” of CNTs produced by chemical vapor deposition The drawn CNT sheet consists of interconnected and oriented multiwalled CNTs Twist insertion produces the twisted yarn that is stable “Overtwisting” generates a coiled yarn structure that is generally not stable when released Dipping the yarn into molten wax fills the pore space with paraffin Solidification of the wax by cooling can fix the coiled structure when released Other guest materials have also been incorporated into the twisted and coiled CNT yarns including synthetic rubbers Chun et al 2014 Other host materials have also been recently reported like niobium nanowire yarns Mirvakili et al 2013In the selection of carbons for use as the electrode material in electrochemically driven actuators the primary factor of choice is the specific surface area of the carbons Generally an actuator that has higher capacitance also has higher actuation performance however this principle is valid in the extent of the same electrode material only Palmre et al 2009
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