early 2000, triarylamine (TA)‐based aromatic polymers especially the PIs and PAs have drawn considerable attention from the research community as the fourth‐generation EC materials. The correlation between electrochemical properties and chemical structures of different aromatic PIs was firstly described in 1990. Ten years later, Zhiyuan Wang and coworkers [14] reported the first EC behavior of poly(ether naphthalimide)s, which showed stepwise coloration process, from colorless to red and to dark blue corresponding to the neutral, radical anion, and dianion species, respectively. However, due to the high rigidity of the PIs/PAs backbone and strong intermolecular interactions, the poor processability limited the development of PIs or PAs EC materials. Therefore the TA groups were introduced to the PIs/PAs backbone to improve the solubility of aromatic polymers. The first TA‐based polyamide PA was synthesized in 1990 [15], and the first aromatic polyimides integrating interesting EC properties containing TA groups were disclosed in 2005 [16]. Since then, Liou, Hsiao and, other groups have developed numerous TA‐based EC PIs/PAs. Most of the PIs/PAs were solution processible and thermally stable with excellent adhesion with indium tin oxide‐coated glass electrode and had good electrochemical stability. Now the TPA‐based PIs/PAs are considered as great anodic EC materials due to proper oxidation potentials, electrochemical stability, and thin‐film formability.
Benefiting from the bloom and revolution of organic polymers, metallo‐supermolecular polymers were developed by incorporating metal centers into synthetic polymer chains, as the fifth‐generation EC materials. The first metal‐containing polymer, poly(vinyl‐ferrocene), was reported in as early as 1955 [17]. However, due to the insolubility of those macromolecules and the limitation of characteristic technologies in the early years, the metallo‐supermolecular polymers haven't been rapidly developed until the mid‐1990s [18]. Since then, metallo‐supermolecular polymers began to be widely explored in EC field with the advantages of beneficial properties of both organic and inorganic materials. Especially, because the transition metal complexes often exhibit well‐defined redox events and intense charge transfer transitions in the NIR region, metallo‐supermolecular polymers often show potentials in NIR EC application.
More recently, with the active researches on the crystalline and porous MOFs and COFs, the sixth‐generation MOFs/COFs EC materials have emerged. In 2013, the first EC properties of MOFs using naphthalene diimide (NDI) as organic linker were reported by Professor M. Dinca's group [19]. And the first COFs EC material using the TPA as building block was revealed by Yuwu Zhong and Dong Wang and coworkers in 2019 [20]. All in all, some essential features of MOFs/COFs give them advantages in EC, including designable and precise molecular structure, simple self‐assembly synthesis, and porous structure that facilitate the electrolyte ions transport. However, these new EC materials haven't been fully revealed; many efforts should be taken to improve the device performance of MOFs/COFs‐based electrochromism.
1.3 The Key Parameters of Electrochromism
In order to elucidate the EC properties of EC materials, in situ UV–Vis–NIR spectroelectrochemistry (SEC) measurements were performed on a spectrophotometer, combining with an electrochemical workstation to apply and control the potential in the SEC cell. This SEC spectrum dynamically records the absorption change of EC materials during different applied voltage, which reflects the color change during the whole redox process. As an example, the SEC of a black‐to‐transmissive EC material is shown in Figure 1.4. Both absorbance model and transmittance model could be used to carry out the SEC measurement.
Figure 1.4 The spectroelectrochemistry (SEC) of a black‐to‐transmissive EC material. (a) Absorbance model and (b) transmittance model.
Source: Reproduced by permission Li et al. [21]. © 2018, Royal Society of Chemistry.
1.3.1 Electrochromic Contrast
EC contrast (Δ%T) is measured as the percent transmittance change of the EC material at a specific wavelength [22] it is a primary parameter for characterizing the EC materials. It is calculated from the difference of light transmission (TM) in the bleached and colored state TMb and TMc at the specified wavelength. And the transmittance values are generally recorded upon the application of square‐wave potential steps to the electroactive film placed in the beam of a spectrophotometer. Each color has a characteristic wavelength as shown in Figure 1.5b, such as the wavelength of blue color is ranging from 455 to 490 nm. Therefore, in most cases, the contrast in the characteristic wavelength is chosen to evaluate the degrees of color change. Usually the absorption of this characteristic wavelength also reaches its maximum value (λmax). Moreover, there is evidence that human eyes are most sensitive to green light with a wavelength of 555 nm [25]. It's also recommended to calculate the contrast in 555 nm for comparison in different publications. Specifically, a contrast test example is shown in Figure 1.5a, the TMb and TMc of λmax 425 nm are 1% and 99%, respectively; therefore the Δ%T is calculated as 98%. For applications such as smart windows, in which the difference between the bleached and colored states is expected to be the highest, the Δ%T should be higher than 80%. Many inorganic EC materials, organic small molecules, and PEDOT series polymers, which have a high transmittance in the bleached state, can achieve this index. Especially, some reported small molecule EC materials even show Δ%T exceed 95% [23].
Figure 1.5 (a) The electrochromic contrast of a small molecule EC material.
Source: Jiang et al. [23]
, (b) sensitivity function of the human eye V(λ) and luminous efficacy vs wavelength.
Source: Fred Schubert [24]. © 2006, Cambridge University Press.
(c) The change of the lightness values from the neutral to the oxidized states.
Source: Li et al. [21]. © 2018, Royal Society of Chemistry.
Meanwhile, for some broad absorption or color‐to‐colorless EC materials, measurements on the relative luminance change (Δ%Y) during an EC switch are more realistic for exhibiting the overall EC contrast, which conveys more information on the perception of transmittance to the human eye. As an example, a luminance change curve during the redox process of black‐to‐transmissive EC materials is shown in Figure 1.5c. The lightness L* value (from 0 (black) to 100 (white)) of 37.5 (black state) increases to 60 (bleach state); therefore the Δ%Y is calculated as 22.5%.
Except for the aforementioned method for electrochemical contrast measurements, a photopically weighted value called photopic contrast was proposed by Javier Padilla et al. [26]. The photopic contrast also reflects an overall contrast during the whole visible region, which is more consistent with the real application condition. It can be calculated using the following equation: