Advances in Inorganic All-solid-state Electrochromic Materials and Devices

doi:10.15541/jim20190305

Abstract

Abstract:

Chromogenic materials are capable of optical change reversibly in response to physical stimuli (e.g., electric field, temperature, illumination, and atmosphere). Among them, electrochromic materials are expected to be widely used in smart windows, screen displays, multi-functional energy storage devices and other fields due to their characteristics such as large adjustment range, fast response rate, high coloring efficiency and good cycle stability. However, compared with semi-solid-state electrochromic devices that are difficult to package and organic electrochromic materials that are prone to denaturation and failure, inorganic all-solid-state electrochromic materials and devices have better comprehensive application. This paper focuses on the typical inorganic all-solid-state electrochromic materials and devices, presents a brief review on the current preparation methods of each structure layer of electrochromic devices and compares its advantages and disadvantages, introduces in detail the main alternative electrochromic materials and its key performance evaluation index, and explains the principle of several representative electrochromic devices, proposes to use transparent flexible electrodes with both high light transmittance, low surface resistance and excellent bending fold to replace the traditional rigid substrate in order to realize multi-field responsible device application development. Finally, the application prospect of inorganic all-solid-state electrochromic devices is prospected from the perspective of performance bottleneck, process difficulty and industrialization opportunity, which provides reference for the industrialization process of electrochromic devices.

Key words: inorganic all-solid-state, electrochromic devices, material selection, structural design, application prospect, review

CLC Number:

TQ174

JIA Hanxiang, CAO Xun, JIN Pingshi. Advances in Inorganic All-solid-state Electrochromic Materials and Devices[J]. Journal of Inorganic Materials, 2020, 35(5): 511-524.

Figures/Tables 24

Fig. 1 Schematic diagram of chromogenic system (a) Al3+ based electrochromic device and its light modulation[11]; (b) Gate-controlled VO2 phase transition by tuning hydrogenating level for high-performance smart windows[12]; (c) Illustration of reversible photochromic reaction in PC-PCN (photochromic porous coordination network)[13]; (d) Schematic description of the adsorption and diffusion of a H atom along WOx based gasochromic thin film[14]

Fig. 2 Schematic diagram (a) and photographs (b-e) of flexible electrochromic device of Ag/W18O49 nanowire co-assemble[17]

Fig. 3 Schematic illustrations of functioning mechanisms for the bi-functional device[18]

Fig. 4 Performance index of the functional layers of inorganic all-solid-state electrochromic device

Fig. 5 Schematic diagram of typical electrochromic device structure[10]

Fig. 6 The key performance evaluation index of typical electrochromic device

Table 1 Electrochromic materials and their deposition methods

Category	EC Layer	Preparation method
Cathod coloration	WO₃	Magnetron sputtering^[23], vacuum evaporation, Sol-Gel
	MoO₃	Magnetron sputtering^[24], vacuum evaporation^[25]
	Nb₂O₅	Anodic oxidation^[26]
	TiO₂	Hydrothermal^[27]
Anode coloring	NiO_x	Magnetron sputtering
	IrO₂	Anodic oxidation^[28]
	CoO₂	Hydrothermal^[29]
	Prussian blue	Electrochemical deposition^[30]

Fig. 7 Schematic illustration of the preparation for electrochromic electrodes with and without a graphene interface layer[31]

Fig. 8 Pictures of gel films on FTO glass[32] (a) Immediately after spraying; (b) After 12 h of hydrolysis

Fig. 9 Schematic illustration for the formation of Co3O4 macro- bowl array films[33]

Fig. 10 Synthesis of Nb2O5 thin films grown by single source precursor CVD[34]

Fig. 11 Ag/W18O49 nanowire co-assembles prepared by L-B technique[17]

Fig. 12 Schematic diagram of the fabrication process of the hybrid electrochromic electrode based on self-forming crackle pattern technology[35]

Fig. 13 Ag grid/PEDOT hybrid flexible eletrode film[36] (a) Schematic illustration of the structure of the silver grid/PEDOT:PSS hybrid film; (b) Low- and high-magnification SEM image of the hybrid film; (c) EDS mapping of the hybrid film, demonstrating the uniform distribution of PEDOT:PSS across the whole film

Fig. 14 Scheme of a new ESS window device system (a) and schematic for the device preparation process (b)[16]

Fig. 15 Transmittance and optical modulation changes of the WO3 on the silver grid/PEDOT:PSS hybrid film in the bleached and colored state[36] (a,b) Under repeated compressive bending; (c,d) Under repeated tensile bending. Curvature radius is 20 mm

Fig. 16 SEM cross-section image of ECD-fresh: Glass/ITO/ WO3/LiTaO3/NiO/ITO[52]

Fig. 17 SEM cross-sectional images (a-b) of ECD-1 and ECD-2 with and without the embedment of Ta2O5 layers[53]

Fig. 18 Electrochromic response of W18O49 nanowires under electrochemical insertion from one of the three different ions: Li+, Na+, and Al3+ in organic polycarbonate (PC) solvent using ClO4- as counter ion under ambient conditions[54] (a) CV curves (solid: the 1st cycle, broken: the 30th cycle) of the W18O49 nanowires film at a scan rate of 10 mV·s-1 in 1.0 mol/L PC-Al(ClO4)3, PC-LiClO4, PC-NaClO4; (b) In situ transmittance variation curves between colored and bleached state for W18O49 nanowires film in 1.0 mol/L PC-Al(ClO4)3, PC-LiClO4, and PC-NaClO4. Solid and broken lines are for the 1st and 30th cycle, respectively; (c) Full plot of the in situ transmittance variation in the three non-aqueous solutions, a total of 30 cycles; (d) In situ OD variation as a function of charge density monitored at wavelength of 633 nm in PC-LiClO4, PC-NaClO4, PC-Al(ClO4)3

Fig. 19 Electrochromic performance of WO3 films under various operations[58] (a) Comparison of optical response at 550 nm and for 1.5-4.0 V with and without constant loading current, inset shows a magnified view of the transmittance during 20 initial cycles at 10 mV·s-1; (b) CV data for different cycle numbers at 10 mV·s-1; (c) Trapped and extracted charge densities vs cycle number derived from CV data

Fig. 20 Electrochromic properties of NiO nanoparticles film with seed layer on ITO glass[61] (a) Transmittance spectra of the NiO nanoparticles film with seed layer on ITO glass in the bleached (0.2 V) and colored (0.6 V) states in the wavelength range of 300-900 nm, with inset showing the digital photos of NiO film growing on ITO glass with seed layer on bleached state and colored state; (b) Current response for NiO nanoparticles film at 0.2 and 0.6 V applications in 1 mol/L KOH for 30 s per step; (c) Corresponding in situ optical responses of NiO films for 30 s per step measured at 550 nm; (d) Cycle performance of the NiO nanoparticles film measured in 1 mol/L KOH for 5000 cycles

Fig. 21 LixNiOy all-solid-state ECDs based on gradient Li+ distribution and its performance (a) Schematic diagram of Li ions transportation in the ECD-1 for the coloration process; (b) Schematic diagram of Li ions transportation in the ECD-2 for the coloration process; (c) Comparison of the transmittance variety at 670 nm of LixNiOy-based ECD and NiOx-based ECD at 2.5 V bias; (d) Comparison of this work with recently reported all-solid-state ECDs

Fig. 22 Schematic representation for the LBL fabrication of the multilayered (LDH/PB)n electrochromic film[63,64]

Fig. 23 All-solid-state electrochromic devices developed by our research group

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