Electrochromic Enhancement of WO<sub>3</sub>-TiO<sub>2</sub>Composite Films Produced by Electrochemical Anodization

Gui, Yang; Blackwood, Daniel John

doi:10.1149/2.0631414jes

Cited by 30 publications

(10 citation statements)

References 64 publications

(93 reference statements)

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“…The electrochromic performance of the spray pyrolysed Ti:WO 3 thin films improves significantly on Ti doping in a similar way as that previously reported in the literature [45][46][47]. The durability of the electrochromic behavior is increased when WO 3 films are doped with Ti atoms.…”

Section: Discussionsupporting

confidence: 84%

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

et al. 2015

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Section: Discussionsupporting

confidence: 84%

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

et al. 2015

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“…The obtained data are displayed in Figure A, and it is apparent that all three samples have very similar impedance profiles: a semicircle in the high‐frequency range, and an up‐sloping curve in the low‐frequency range bending towards to the x ‐axis. Such a profile is commonly observed in supercapacitors and is usually modeled with the equivalent circuit shown in Figure B, where: R S implies the series resistance which is usually composed of several components including resistance of the NaOH electrolyte, contact resistance, as well as the resistance of the electrode; R CT is the resistance of charge transfer process from the electrolyte to the film; CPE dl represents a constant phase element originating from the double layer capacitance; R L stands for the leakage resistance of the supercapacitor; W S is the a finite length Warburg impedance (short circuit) associated with the diffusion of ions inside the film; and CPE in is the constant phase element showing the capacitance rising from insertion of the ions in the surface region of the copper oxide film …”

Section: Resultsmentioning

confidence: 99%

“…Such a profile is commonly observed in supercapacitors and is usually modeled with the equivalent circuit shown in Figure 7B [67,68] where: R S implies the series resistance which is usually composed of several components including resistance of the NaOH electrolyte, contact resistance, as well as the resistance of the electrode; R CT is the resistance of charge transfer process from the electrolyte to the film; CPE dl represents a constant phase element originating from the double layer capacitance; R L stands for the leakage resistance of the supercapacitor; W S is the a finite length Warburg impedance (short circuit) associated with the diffusion of ions inside the film; and CPE in is the constant phase element showing the capacitance rising from insertion of the ions in the surface region of the copper oxide film. [69] All the fitted data of these elements, along with parameters indicating the high quality of the fits, are listed in Table 1. It can be seen that the time constants (t) of the Warburg elements are of the order of 10 s, from which the diffusion length (L) can be calculated [Eq.…”

Section: Resultsmentioning

confidence: 99%

Sodium‐Salt‐Promoted Growth of Self‐Supported Copper Oxides with Comparative Supercapacitive Properties

Chen

Huang

et al. 2017

ChemElectroChem

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In this work, we developed a facile hydrothermal system to synthesize self‐supported copper oxides with different nanostructures. In this system, we used copper foam as both the substrate and the copper source, and selected a wide range of sodium salts to serve as directing agents, promoting the formation of copper oxide with different nanostructures. We first show that, at 30 mM of sodium fluoride, we can successfully grow nanocubes on the copper foam substrate that comprise both CuO and Cu2O. Such a mixed composition is unique among the investigated salts. However, if a lower concentration of NaF or a different salt is used, Cu2O nanocrystals of different structures, such as nanoplatelets or irregular particles, can be obtained. When these samples were tested in supercapacitors, they demonstrated contrasting pseudocapacitive properties where the initial mixed Cu2O/CuO nanocube sample demonstrated a very stable reversible capacitance of about 400 mF cm−2 for 1600 cycles. This is significantly higher than that for the other samples, as well as advantageous compared to other copper‐oxide‐based electrode materials. The impedance analysis suggested that such a performance could be attributed to the low diffusion resistance of this sample.

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“…25 The RF power to the tungsten and titanium targets were 90 W and 15 W giving sputtering rates of about 6 nm min −1 and 1 nm min −1 respectively. As there are losses during the sputtering process, the actual atomic ratio can only be determined by EDS after co-sputtering.…”

Section: Methodsmentioning

confidence: 99%

Honey-Comb Structured WO₃/TiO₂Thin Films with Improved Electrochromic Properties

Gui

Blackwood

2015

J. Electrochem. Soc.

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The electrochromic properties of 90:10 WO 3 /TiO 2 thin films produced by anodizing co-sputtered W/Ti films in a fluorinated ethylene glycol solution are investigated in relation to corresponding pure WO 3 films. SEM images revealed that the TiO 2 content resulted in a more open honey-comb structure that increased the charge accommodation ability by 250%. The superior charge storage property of the WO 3 /TiO 2 meant that it had a better light modulation range, with transmittance of <1% at 800 nm in the colored state. The electrochromic kinetic processes associated with coloration and bleaching are also much faster in the presence of TiO 2 , with data generated by electrochemical impedance spectroscopy revealing that this is due to a reduction in the resistance to the insertion of Li + ions. Materials characterization techniques revealed that the WO 3 /TiO 2 composite maintains the monoclinic structure of the WO 3 and that the Ti atoms are substituted into the WO 3 matrix, rather than forming discrete 8 This especially important in the tropics where air-conditioning usage is high, in part due to architects making extensive use of aesthetically pleasing glass.However, unless the WO 3 is made via expensive high vacuum techniques, some of its properties, such electrochromic reversibility, stability or optical modulation, fall short of those required for a practical smart window. Since these drawbacks have proven difficult to overcome in a pure WO 3 system there have been a number of attempts to solve them by doping or mixing with other electrochromic materials, usually another transition metal oxide. [9][10][11][12][13][14][15][16] In 2005, Patil et al.17 investigated the effect of TiO 2 additions on the electrochromic properties of tungsten trioxide films prepared through spray pyrolysis, finding improved electrochromic reversibility, but not any real enhancement of the coloration efficiency. 17One possible way to improve electrochromic efficiency is to tailor the morphology of the oxide to have spacious channels that can aid charge/ion injection into and transport within the film.18-20 One approach to achieve this is by electrochemical anodization. In 2009 Zheng et al., 7 successfully formed a macro-porous WO 3 thin film by anodizing pure tungsten, which had been deposited onto conductive fluorine doped tin oxide (FTO) glass by a magnetron sputtering method, in NH 4 F aqueous electrolyte. This success provides and broadens the application of electrochromic WO 3 thin films on "Smart Windows" where the transparent substrate is essential. However, these authors only focused on the fabrication of WO 3 thin film with macro-porous structure on FTO glass, giving neither details nor further exploration of the electrochromic properties.Besides efforts have been directed at improving electrochromic properties by producing mixed transition metal oxide films, most notably WO 3 /TiO 2 , by techniques such as electron beam deposition, sputtering, hydrothermal and the sol-gel method. 17,[21][22][23] Although the synthesized film...

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Electrochromic Enhancement of WO₃-TiO₂Composite Films Produced by Electrochemical Anodization

Cited by 30 publications

References 64 publications

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

Sodium‐Salt‐Promoted Growth of Self‐Supported Copper Oxides with Comparative Supercapacitive Properties

Honey-Comb Structured WO₃/TiO₂Thin Films with Improved Electrochromic Properties

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Electrochromic Enhancement of WO3-TiO2Composite Films Produced by Electrochemical Anodization

Cited by 30 publications

References 64 publications

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

Electrical, optical and electrochromic properties of Ti:WO3 thin films deposited by the pulsed chemical spray technique

Sodium‐Salt‐Promoted Growth of Self‐Supported Copper Oxides with Comparative Supercapacitive Properties

Honey-Comb Structured WO3/TiO2Thin Films with Improved Electrochromic Properties

Contact Info

Product

Resources

About

Electrochromic Enhancement of WO₃-TiO₂Composite Films Produced by Electrochemical Anodization

Honey-Comb Structured WO₃/TiO₂Thin Films with Improved Electrochromic Properties