substrates and PEDOT:PSS electrodes as well as the repeat‐unit structures of (a) ECP‐Cyan, (b) ECP‐Magenta, (c) ECP‐Yellow, and (d) ECP‐Black. R = ethylhexyl.
Source: Lang et al. [55].
Figure 2.3 A fabrication process for lateral paper ECDs showing inkjet‐printed PEDOT:PSS electrodes, deposition of ECPs, and [EMI][TFSI]/PVDF‐HFP ion gel electrolyte layer. Devices are operated by applying a 0.8 V bias across the two lateral pixels.
Source: Lang et al. [55].
2.3.2 Self‐Healing Polymer Electrolytes
A self‐healing material is a material that possesses abilities to partially repair damage and restore mechanical properties during its service lifetime [56]. Self‐healing materials are particularly attractive in the field of smart materials because of their inherent ability to repair cracks, thereby avoiding such risks, reducing waste, and improving equipment life, durability and reliability. It is believed that the use of an EC polymer film with self‐healing properties would be an effective approach to overcome the risk of the scar generation in ECDs. Until now, self‐healing polymers based on the Diels–Alder (DA) reaction [57] is an effective method for the implementation of intrinsic self‐healing into functional materials, which have been explored for various electronic and optoelectronic applications like conducting films [58], organic light‐emitting devices [OLEDs] [59], supercapacitors, etc. [60] Self‐healing can come up from the microscopic to macroscopic level. Some properties in engineering materials may degrade over long time because of environmental conditions, fatigue or operation damage. Self‐healing materials can address this kind of degradation. The ability to self‐heal upon breakdown or damage depends on various kinds of physical interactions such as hydrogen bonding [61], π–π stacking [62], ion dipole interaction [63], or chemical interactions such as disulfide bond [64, 65] and imine bond. [66] They heal autonomously or in response to a multitude of externally applied stimuli such as pH change, light [67], electricity, temperature [68], and pressure. Geubelle and coworkers first reported a completely autonomous man‐made self‐healing material [69]. Later, an epoxy system containing microcapsules covered with (liquid thermosetting) monomers was explored [70]. If a microcrack occurs in the system, the microcapsule breaks and the crack will be filled by the monomer. This novel self‐healing system could be performed well in polymers and polymer coatings [71].
Zhang and coworkers [72] prepared a dual physically cross‐linked hydrogel containing the hydrogen bonding between poly(acrylamide‐co‐acrylic acid) and PVA, hence producing self‐healing abilities in hydrogel. As was reported, ion gels with self‐healing performance, which composed of polymer networks and electrolyte solutions, have attracted great attention [73]. Different strategies and approaches to devise self‐healing materials in ECs have been investigated. For example, multifunctional EC ion gels were enabled by a blend of active methyl viologen dication in polystyrene‐block‐poly(methyl methacrylate)‐blockpolystyrene (PS‐PMMA‐PS) triblock copolymer with ILs [74]. Poly[styrene‐ran‐1‐(4‐vinylbenzyl)‐3‐methylimidazolium hexafluorophosphate] (P[S‐r‐VBMI][PF6]) random copolymer (Figure 2.4) [75], poly(styrene‐ran‐methyl methacrylate) (PS‐rPMMA) random copolymer [76], (poly(methyl methacrylate)‐b‐polystyrene)6 star‐shaped block copolymer (Figure 2.5) [77], and poly(vinylidene fluoride‐co‐hexafluoropropylene) (PVDF‐co‐HFP) [78], etc. matrices have been developed for achieving self‐healing solid PEs. The ion conductivity of PVDF‐co‐HFP‐based polyelectrolytes could be improved by using various PVDF‐co‐HFP‐based polymers and amorphous polymer electrolytes such as PEG [78], PMMA [79] and poly(vinyl acetate) (PVAC) [80, 81]. In addition, materials containing IL/polymer blends for self‐healable EC have been reported in Leong's group [82]. The interaction of polymer blends or the inclusion of reaction sites and addition of ILs may induce rapid healing at lower temperatures, attributing to the increased fluidity and inhibition of the glass transition temperatures. Moreover, self‐healing polymers based on DA reaction [83] is another effective method for self‐healing functional materials. A polymer N‐(4‐aminophenyl)‐N‐phenylbenzene‐1,4‐diamine maleimide (DATPFMA) was the first report on a bifunctional self‐healing EC polymer, which exhibited superior cyclic stability and colors variations [57]. The N,N′‐bis(4‐aminophenyl)‐N,N0‐diphenyl‐1,4‐phenylene diamine used as core and electro‐active unit for synthesizing the polymer poly(pentafluorophenyl methacrylate) (PPFMA) provided more electrochemical active sites to enhance the EC performance (Figure 2.6) [84]. This DA polymer can also repair cracks by retro‐DA and DA reaction for the self‐repair capability [57].
Figure 2.4 Synthetic routes for P[S‐r‐VBMI][PF6].
Source: Seo and Moon [75].
Figure 2.5 Synthetic routes for (PS‐b‐PMMA)18.
Source: Jang et al. [77].
Figure 2.6 (a) The mechanism of self‐healing process for electrochromic PPFMA film and (b) the retro‐DA and DA reaction for self‐healing polymer PPFMA.
Source: Zheng et al. [84].
However, developing a material that simultaneously exhibits excellent EC properties and good self‐healing behavior at low temperature is still an unmet challenge, such as large optical contrast, high coloration efficiency, and long‐term, stability, and fast healing process.
2.3.3 Cross‐linking Polymer Electrolytes (CPEs)
The high ionic conductivity of PEs at low temperature is related to the amorphous nature of the polymer matrix (Figure 2.7). The cross‐linked PEs show good ionic conductively and amorphous feature [85]. Cross‐linking was reported to improve the dimensional stability and increase the dynamic storage modulus of the PE. This technique was used to modify positively various PE properties [86, 87], while brittleness, low elasticity, and processability inevitably occur in cross‐linked polymer [88]. In the study of lithium salts‐based electrolytes, PEO, PMMA, PVC, etc. were commonly organized into cross‐linked PEs. Matsui et al. have prepared a cross‐linked PE of poly(ethylene oxide) 2‐(2‐methoxy ethoxy) ethyl glycidyl ether with and without allyl glycidyl ether P(ethylene oxide [EO]/2‐(2‐methoxyethoxy)ethyl glycidyl ether [MEEGE]/allyl glycidyl ether [AGE]) complexed in LiN(CF3SO3)2 salts [89]. Kuratomi et al. studied a cross‐linked copolymer of ethylene oxide and propylene oxide with LiBF4 or LiN(CF3SO2)2