Electrochromic Electrodes with Enhanced Performance: Review of Morphology and Ion Transport Mechanism Modifications

Abstract

The electrochromic (EC) performance of smart windows is highly dependent on the rate of ions insertion/extraction. A direct way to increase the ion exchange in EC device is to modify the structure of the EC electrodes. Structural changes also affect the electrical conduction between the transparent electrodes and the EC layers, leading to efficient smart windows. In more detail, modifying the structure of the EC electrodes results in an increase in the surface-to-volume ratio, which is combined with the increase in charge transfer reaction between the insertion and extraction of ions. The current review summarizes the enhancement in the EC performance due to the fabrication of nano/microstructures or hybrid structures on the surface of the EC electrodes to increase their surface area. Moreover, metal oxide thin films have poor electrical conduction, which leads to a high charge transport barrier. Accordingly, improving the electrical conductivity of the EC layer is considered another effective strategy to enhance the ion transport between the transparent conductor layer and the EC electrode. This behavior could be applied by combining the transition metal oxide with metallic nanoparticles or suitable organic/inorganic transparent conducting materials.

1. Introduction

Smart windows are optoelectronic devices that control the transmission of solar radiation into buildings [1,2]. They are based on electrochromic (EC) materials, which turn from colored to transparent (bleached) states by changing the polarity of the biasing [3]. Using this application, we can control the amount of natural light passing into the building. In addition, it is used to block undesirable radiation such as ultraviolet (UV) or infrared (IR). Furthermore, it provides a better view for the buildings without losing privacy. The complementary smart windows are typically composed of two transparent conductors (TC), two EC materials and a polymer electrolyte [4,5]. Efficient smart windows require layers with a high optical modulation, chemical stability and high optical memory. The optical modulation is mainly dependent on the properties of the EC layer. They are classified electrically into two types: anodic and cathodic EC electrodes [6]. There is a wide range of materials that can be used as electrochromic layers. Among them, nickel oxide (NiO) and tungsten oxide (WO₃) thin films are the most widely used as anodic and cathodic EC electrodes, respectively.

Various physical and chemical fabrication methods have been studied to fabricate electrochromic thin films with different qualities and controlled parameters. For instance, NiO were prepared by electrodeposition [7], Prussian blue (PB) by spray pyrolysis technique [8], WO₃ by pulsed spray pyrolysis technique [9], NiO by sputtering [10] and Molybdenum trioxide (MoO₃) by sol-gel method [11]. The EC performance of compact metal oxides can be improved through different strategies. For instance, research efforts were made by modifying the morphology of the surface of the used transition metal oxide. This improvement is attributed to the increase of the ion injection into the active layer, in addition to shortening the time between the insertion and extraction of ions.

The fabrication of porous structures on the surface of the EC electrodes [12] or performing hybrid nanostructures [13,14] are some examples of this idea. Furthermore, compact metal oxide thin films have a poor electrical conduction, which leads to a high charge transport barrier [15] and, consequently, a low EC performance. Therefore, the EC performance of the EC electrodes can be improved by different strategies: for instance, by doping the metal oxide with metallic nanoparticles, e.g., lithium [16], zinc [17], copper [18], cobalt [19] and silver [20], or by increasing the surface of the active area through performing micro/nanostructured surface of the EC electrodes [21,22,23,24] or combining with conducting polymers such as poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) [25] and copolymers such as PEDOT:PSS and PANI:PSS [26], 2,5-dithienyl-N-substituted-pyrrole (SNS) conjugated with 3,4-Ethylenedioxythiophene (EDOT) [27]. This combination leads to a better electrical transport between the EC electrode and the TC surface.

Due to the large advances in the performance of smart windows offered by such designs, it is important to summarize them in a review that provides a guide for researchers on this topic. One way to increase the performance of the electrochromic devices is to increase the surface to volume ratio of the electrochromic electrodes using nano/microfeatures [28,29,30]. The structural modification of the surfaces can be periodic, regular or random and may combine two types of materials: organic and inorganic. The hybridization of organic and inorganic materials in their nanostructure form gives a complex structure that collects the advantages of the three terms. Where the organic materials in general are easy to process and have low cost. The inorganic materials have high durability and stability, while nanofeatures increase the surface-to-volume ratio.

We collected both recent methods and structures applied to develop the EC performance of the anodic and cathodic electrodes of smart windows. We based our review on these topics considering the recent reports and high-performance results. The first part of the review summarizes some categories of nanostructured EC electrodes (random or periodic surface structures) and how they remarkably enhanced the EC performance of the electrodes. The next part presents the outstanding EC performance by combining nano/microstructures on the surface of the EC electrodes. This behavior is attributed to the increase in the surface-to-volume ratio. Finally, the hybridization of organic/inorganic materials creates new composite with custom EC properties. The combination of the organic and the inorganic material helps to mitigate the poor electrical conduction of the transition metal oxides, which leads to a high charge transport barrier. This arrangement collects the various structures, materials, and methods applied in this line to give a short compact capsule about advanced EC devices.

Table 1. Comparison between the previously published review articles and the current work.

Title of the Review Article	The Scope of the Article	Reference
Nanostructured electrochromic smart windows: traditional materials and NIR-selective plasmonic nanocrystals	Overview of current state-of-the-art conventional electrochromic materials	[31]
Nanostructured materials for electrochromic energy storage systems	Description of new active materials, distinct assembly techniques and transparent conductive electrodes used for developing a more efficient smart windows	[32]
A Brief Overview of Electrochromic Materials and Related Devices: A Nanostructured Materials Perspective	The paper discusses the causes of internal and external size effects in the process of modifying WO3 electrochromic films using nanomaterials	[33]
Nanostructured inorganic electrochromic materials for light applications	Summarizes the classifications of electrochromic materials, including inorganic materials (e.g., transition metal oxides, Prussian blue, and polyoxometalates), organic materials (e.g., polymers, covalent organic frameworks, and viologens), inorganic-organic hybrids, and plasmonic materials.	[6]
Electrochromic electrodes with enhanced performance: Review of morphology and ion transport mechanism modifications	Summarize direct ways to increase the ion exchange in EC device due to modifying surface morphology and composition of the EC electrodes.	Current review

presents a comparison between the previously published review articles in the same field and the present work.

2. Strategies to Modify the Morphology of the Electrochromic Electrodes

2.1. Nanostructured Periodic Arrays

Surface texture is a method that is widely used to manage light propagation in optoelectronic devices. In smart windows, a solid electrolyte is usually casted between the two EC layers. Texturing the surface of the EC layer increases the adhesion between the solid electrolyte and the EC layer and increases the surface-to-volume ratio between them. This behavior leads to an enhancement in the coloration efficiency by increasing the amount and rate of ion injection and extraction in the device. Furthermore, this design reduces the diffusion path for the ions in a complete cycle through the device. Regular geometry that is repeated over long spatial range is called periodic nanostructure arrays. These designs are widely used in electrochromic applications to enhance the performance of the electrodes. Various geometrical shapes reveal a high coloration efficiency (CE). Core-shell structure reveals a CE of 104.6 cm²/C, which decreased by only 11.8% after 1000 cycles [34]. Recently, hybrid core–shell-type nanostructures were used to fabricate electrochromic devices with optical modulation of 45% [35]. The obtained CE is more than 145 cm²/C, which is retained after 1500 cycles without significant degradation. The combination of core-shell structure with nanowire applied to flexible transparent electrodes enhances the electrochemical stability and the electrochromic performance of the device [36]. A high optical modulation of 72% at 550 nm was achieved. Both electrical conductivity (ΔR/R ≈ 8.3% and 14%) and electrochromic performance (90% and 92%) maintained after 20,000 bending cycles. Moreover, the CE reaches a value of 79.49 cm²/C. Many other nanostructured designs were applied to enhance both CE and durability by maintaining their initial performance after hundreds and thousands of cycles. Some recent examples are based on quantum dots [37], nanofibers [38], hierarchical nanostructures [39], nanorods [40], nanowires [41] and nano-flower shape structure [42]. Most of these structures can be fabricated using chemical-based techniques, which means low cost and scalable fabrication availability.

The combination between self-assembled colloidal method with electrodeposition is used to fabricated well-ordered nanoholes or nanopore NiO films [12]. Y.F. Yuan et al. studied the comparison between the electrochromic performance of compact NiO thin films and ordered porous NiO films [12]. The structure was prepared by electrodeposition using a self-assembled colloidal crystal template. The electrochromic properties were investigated in an aqueous solution of KOH (0.1 M). Figure 1a portrays the morphology of the ordered porous NiO thin film. Figure 1b shows the comparison between the optical transmittance in the colored and bleached states in the 200 to 900 nm wavelength range for the compact and the ordered porous NiO thin layers. From the reported experimental data, the optical modulation ($\Delta \mathrm{OD}(\mathsf{\lambda })$) at 550 nm for the ordered porous NiO thin layer is 76% while it is only 51% for the compact one. Furthermore, Figure 1c shows the cyclic voltammetry behavior for the two structures of NiO thin films. Accordingly, the cathodic and anodic peak currents for the modified porous structure are higher than those of the compact NiO thin film. As a result, an improvement in the switching speed, optical modulation, and coloration efficiency (η) is obtained for the porous electrode, where η increased from 27 ${\mathrm{cm}}^2 {\mathrm{C}}^{-1}$ for compact NiO thin films to 41 ${\mathrm{cm}}^2$ ${\mathrm{C}}^{-1}$ for ordered porous NiO thin layer at 550 nm.

2.2. Nanostructured Porous Surfaces

Another design of electrochromic electrodes is the random porous surfaces. In this case, the pores do not take the form of regular geometrical shapes; instead, they take homogeneous or nonhomogeneous spongy shapes. A high optical contrast of 61.4% at 633 nm wavelength was obtained for rare earth Samarium (Sm) doped WO₃ porous thin layer [43]. The nest-like porous Sm-doped WO₃ retained 91.7% of primitive optical contrast after 6000 cycles. The metal doped nanoporous structures allow the multifunctionality of the electrochromic electrodes. As an electrochromic thin film, Cu doped NiO film with assembled nanosheet structure reveals a large optical modulation (77.1% at 550 nm), short color switching time (10.6/14.3 s) and high coloration efficiency (66.3 cm²/C) [44]. As a charge storage electrode, it has a high area specific capacitance of 94.7 mF/cm² at 0.2 mA/cm². A higher area specific capacitance was obtained when nanowire structure was combined with porous film structure [45]. A great enhancement for the CE is obtained for 3D reticular-like porous structure, which increases from 258 cm²/C for the compact thin film structure to 534 cm²/C for the porous structure [46].

The EC performance of TiO₂ thin films is poor when compared with NiO and WO₃. However, the modified designs of TiO₂ show a comparable performance. For example, nanostructured TiO₂ thin films were prepared as efficient electrochromic electrodes by doctor blade method [47]. Figure 2a shows the morphology of the fabricated porous TiO₂ thin film, while Figure 2b shows the transmission of the TiO₂ at 550 nm for different coloration times starting from the as deposited (curve-1) then increase the coloration time till the complete colored state (curve-6) with transmission of (T_c) 10%, then back again to complete bleaching (curve-7). The symmetrical cyclic voltammetry shown in Figure 2c proves the stability of insertion/extraction of Li⁺ from the electrolyte. This structure results in a coloration efficiency of 33.7 ${\mathrm{cm}}^2 {\mathrm{C}}^{-1}$ and fast response of 2 s.

2.3. Nano/Micro Composite Surfaces

Composites involve materials with more than one phase; when processed as thin films they reveal various and tunable physical and chemical properties not likely found in monolithic thin films [53,54]. For this, composite materials with nano and micro features were extensively applied to enhance the performance of EC devices [28,55,56,57]. The idea is the same, increasing the surface-to-volume ratio, besides the tunable physical properties offered by the composite materials. For instance, Gözde Yurdabak Karaca et al. reported a remarkable enhancement in the EC performance of WO₃ thin films when combined with Au, poly (3, 4-ethylenedioxythiophene) (PEDOT:PSS) and Pt microtubes [14]. The resulting composite is an EC thin film with the structure WO₃/Au/PEDOT:PSS/Pt. Figure 3 portrays the top-view and the cross-sectional views of the fabricated microtubes of Au/PEDOT:PSS/Pt composites on WO₃ thin films. Furthermore, Figure 3d,e show the spectral transmittance response for the colored and bleached states of the pure WO₃ thin film and WO₃/Au/PEDOT:PSS/Pt composite electrodes, respectively. Accordingly, the response time was shortened and the optical modulation remarkably increased for the case of WO₃/Au/PEDOT:PSS/Pt electrode. This enhancement is attributed to several reasons. First, PEDOT:PSS is a cathodic electrochromic material, so the coloration in the colored state improved, as shown in the transmittance data in Figure 3e. Furthermore, Au and Pt materials lead to enhancing the electrical conduction between the EC electrode and the TC surface. Finally, the interlinking between the microtubes and the porous structure makes the ions diffusion easier and increase the surface area for charge-transfer reactions. Accordingly, the overall electrochromic performance of the modified WO₃/Au/PEDOT:PSS/Pt structure was enhanced. The coloration and bleaching response time (t_C and t_b) of WO₃/Au/PEDOT:PSS/Pt electrode are t_{C =} 25.86 s and t_{b =} 15.93 s, compared with t_{C =} 19.25 s and t_{b =} 13.83 s for the pure WO₃ electrode. Moreover, $\Delta \mathrm{OD}(\mathsf{\lambda })$ of the WO₃/Au/PEDOT:PSS/Pt composite improved from 21.9% to 26% at $\pm$2 V.

Moreover, Mudaliar Mahesh Margoni et al. fabricated an EC electrode of nano/microstructures of V₂O₅ in the form of nanorods accumulated with microspheres by hydrothermal method [58]. The samples show a high transmittance (maximum average is 77%) and low resistivity (minimum is 7.9 × 10⁻⁴ Ω.cm). These enhanced optical and electrical properties reveal maximum cathodic peak current as 1.8 mA/cm² and a maximum anodic peak current as 2.8 mA/cm². Furthermore, the ion diffusion coefficient was also enhanced, which makes the structure suitable for electrochromic applications. From another perspective, Md Rakibuddin et.al synthesized micro-nanostructure sized tungsten trioxide (WO₃) by thermal annealing of tungsten powder under ambient conditions [59]. The fabricated samples show a high crystallinity. Furthermore, they can tune the size of the WO₃ particles from microscale to nanoscale using the annealing temperature. The powder is then spin coated on FTO glass to obtain the EC electrode. The performance of the EC device based on the fabricated layers was compared with a device based on commercial WO₃. The coloration efficiency enhanced from 30.45 cm² C⁻¹ for the device with the commercial layer to 32.3 cm² C⁻¹ for the device with the fabricated WO₃ layer. An optimized electrochromic device based on this micro-nano WO₃ layer may result in a better coloration efficiency.

2.4. Hybrid Organic-Inorganic Nanocomposite EC Surfaces with Nanofeature

Organic materials are widely applied in optoelectronics, as they are, in general, solution-processed and low cost [60,61]. Despite the enhancement in the CE of organic materials, low durability due to its degradation is a general feature [62]. The idea of hybridization between organic and inorganic electrochromic layers with nanofeatures takes advantage of the three of them [63,64,65,66]. This allows the production of high-performance, low cost and long-cyclic stability EC devices [67,68]. Haizeng Li et al. recently studied the electrochromic properties of organic-inorganic nanocomposite film [25]. The film is composed of inorganic material (porous layers of tungsten molybdenum oxide nanorods W_0.71Mo_0.29O₃) permeated with an interconnected conductive organic layer of PEDOT:PSS. In the reported study, the EC properties of the conjugated polymer of W_0.71Mo_0.29O_3/PEDOT:PSS were compared with the W_0.71Mo_0.29O₃ and PEDOT:PSS alone. The purpose of the combination between the organic and the inorganic material is to mitigate the poor electrical conduction of the transition metal oxides, which leads to a high charge transport barrier. Figure 4a shows the typical morphology of the fabricated porous W_0.71Mo_0.29O₃ electrode, while Figure 4b portrays the morphology of the nanocomposite after the growth of the PEDOT:PSS layer. Filling in the pores of porous W_0.71Mo_0.29O₃ electrode with PEDOT:PSS leads to increasing the pathway for charge transportation. This behavior is expected to decrease the charge transport barrier and enhance the electrochromic performance. Figure 4c shows the optical behavior of the hybrid organic-inorganic EC electrode in the colored and bleached states at $\pm 1\mathrm{V}$ in 1 M LiClO₄-propyline carbonate solution. The optical contrast of the mixed composite is 65.1% at 632.8 nm, which is higher than both W_0.71Mo_0.29O₃ (54.5%) and PEDOT:PSS electrode (51.4%). Furthermore, Figure 4d summarizes the switching response between coloring and bleaching of W_0.71Mo_0.29O₃ electrode, PEDOT:PSS electrode and hybrid W_0.71Mo_0.29O_3/PEDOT:PSS for the hybrid W_0.71Mo_0.29O_3/PEDOT:PSS electrode, which is given as t_c = 17.9 s, t_b = 10.5 s compared with t_c = 22.1 s and t_b = 13.9 s for W_0.71Mo_0.29O₃ electrode. This response is attributed to the high electrical conduction of PEDOT:PSS layer, which promotes the charge transfer efficiency by providing more active areas in W_0.71Mo_0.29O₃ to interact with Li⁺ in the electrolyte, while, PEDOT:PSS electrode gives the fastest response (t_c = 6.5 s, t_b = 3 s) as a result of its high electrical conduction. Accordingly, the coloration efficiency of the hybrid W_0.71Mo_0.29O_3/PEDOT:PSS electrode is 52.8 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$, twice more than that of W_0.71Mo_0.29O₃ electrode (21.7 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$).

Hybrid nanostructures of PEDOT:PSS and graphene oxide (GO) layer are another example of hybrid nanocomposites leading to enhancing the electrochromic performance of smart windows. Yingdi Shi et al. studied the effect of combining GO nanosheet with PEDOT:PSS EC thin film through the electro-polymerization method [30]. Figure 5a shows the morphology of the pristine PEDOT:PSS layer and Figure 5b shows the morphology after the growth of the GO nanosheet. The FESEM image of PEDOT:PSS layer shows the formation of a rough surface with a high surface area, which favors deeper ion injection into the active layer. Figure 5c,d show the optical behavior for pristine PEDOT:PSS and hybrid PEDOT:PSS/GO nanostructures from 300 nm to 800 nm wavelength range, respectively. Accordingly, the optical contrast between coloring and bleaching increased from 23.4% to 34.4% after the hybridization with GO nanosheet at 480 nm, in addition to shortening the coloring and bleaching time from 1800 ms to 300 ms and 1500 ms to 400 ms, respectively. Moreover, the coloration efficiency improved from 53.5${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ to 64.9 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ due to the hybridization with the GO layer. This enhancement in the EC performance of the hybrid PEDOT:PSS/GO nanostructured electrode is attributed to the increase in the surface-to-volume ratio of PEDOT:PSS layer. In addition, the growth of GO nanosheet functionalized the surface of the PEDOT:PSS layer and contributed as a buffer layer.

According to the results presented in the current review, we predict better EC performance of smart windows because of improving ion insertions and extractions through the fabrication of nanostructured EC electrodes or hybrid nanostructures on its surface. So far, we are thinking of combining the increase in the surface-to-volume ratio by texturing the surface of the EC electrodes and improving the electrical conduction of the transparent electrodes. The first increases the total ion transfer through the device and the second enhances the rate of this transfer, which in turn leads to high optical contrast and fast switching time. The next focus of research may be on applying hybrid organic/inorganic materials in their nano or microforms to the different layers of the device. These combinations involve wide options and selections in both materials and designs that need to be explored through future research.

3. Conclusions

The results provided in the current review summarize some of the remarkable enhancements in the performance of the electrochromic devices due to modifying the surface of the working and counter EC electrodes of smart windows. The reported modification methods are concluded in three points:

• Texturing the EC electrode surface, the implementation of nano/microstructures or hybrid nanostructures on the surface of the EC electrode led to the increase in the surface-to-volume ratio.
• The incorporation with metallic nanoparticles (e.g., Au or Pt) leads to improving the electrical conduction between the electrochromic electrode and the transparent conductor surface.
• The combination with organic transparent conductors (e.g., PEDOT:PSS or PANI:PSS) results in improving the electrical conduction in addition to decreasing the time between insertion and extraction of ions.

Generally, the enhancement in the electrochromic properties of the electrochromic electrodes by the mentioned methods can contribute remarkably to the production of efficient smart window applications. For instance, Y.F. Yuan et al. studied the comparison between the electrochromic performance of compact NiO thin films and ordered porous NiO films, where the efficiency increased from 27 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ for dense NiO thin films to 41 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ for ordered porous NiO thin films at 550 nm. Moreover, the fabrication of nanostructured TiO₂ thin films results in a coloration efficiency of 33.7 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ and a fast response of 2 s. From another perspective, Gözde Yurdabak Karaca et al. reported on the remarkable enhancement in the electrochromic performance of WO₃ thin films due to the combination with Au, poly (3, 4-ethylenedioxythiophene) (PEDOT:PSS) and Pt microtubes, where coloration efficiency enhanced from 30.45 cm² C⁻¹ for the device with the WO₃ thin film to 32.3 cm² C⁻¹ for the modified one. In addition, Yingdi Shi et al. reported an enhancement in the coloration efficiency from 53.5${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ to 64.9 ${\mathrm{cm}}^2{\mathrm{C}}^{-1}$ due to combining PEDOT:PSS thin film with graphene oxide nanosheet. According to the results presented in the current review, we predict better EC performance of smart windows because of improving ion insertions and extractions through the fabrication of nanostructured EC electrodes or hybrid nanostructures on their surface.