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Jun 1, 2014, Huige Wei and others published Tungsten Trioxide/Zinc Tungstate Bilayers: Electrochromic Behaviors, Energy Storage and Electron Transfer | Find, read and cite all the research you
Triple Layer Tungsten Trioxide, Graphene, and Polyaniline Composite Films for Combined Energy Storage and Electrochromic Applications Polymers (Basel) . 2019 Dec 30;12(1):49. doi: 10.3390/polym12010049.
A high-performance electrochromic-energy storage device (EESD) is developed, which successfully realizes the
Tri and tri again!Tungsten trioxide (WO 3) has been intensively investigated as an electrode material for different applications because of its excellent charge-transport features, unique physicochemical properties, and good resistance to corrosion, but it suffers from a relatively low specific surface area and low energy density.
Among the different tungsten oxide materials, tungsten trioxide (WO 3) has been intensively investigated as an electrode material for different applications because of its excellent charge-transport features, unique physicochemical properties, and good resistance
Polyaniline (PANI)/tungsten oxide (WO3) nanocomposite films were fabricated by electropolymerization of aniline monomers onto WO3 coated indium tin oxide (ITO) glass slides, which were prepared by spin coating
Large-scale multifunctional electrochromic-energy storage device based on tungsten trioxide monohydrate nanosheets and prussian white ACS Appl. Mater. Interfaces, 9 ( 35 ) ( 2017 ), pp. 29872 - 29880, 10.1021/acsami.7b08656
Tungsten trioxide, WO 3, is a wide bandgap semiconductor with versatile applications. It has become one of the most investigated functional materials due to its unique properties, for example, electrochromism, photochromism, electrocatalysis and photocatalysis [11], [12], [13].
Triple Layer Tungsten Trioxide, Graphene, and Polyaniline Composite Films for Combined Energy Storage and Electrochromic Applications December 2019 Polymers 12(1):49
Bi Z, Li X, Chen Y, et al. Large-scale multifunctional electrochromic-energy storage device based on tungsten trioxide monohydrate nanosheets and Prussian white. ACS Applied Materials & Interfaces, 2017, 9(35): 29872–29880. Article Google Scholar
Lyu H. Triple Layer Tungsten Trioxide, Graphene, and Polyaniline Composite Films for Combined Energy Storage and Electrochromic Applications. Polymers . 2020; 12(1):49.
The enhanced energy storage and electrochromic performances of the PANI-based nanocomposite films can be attributed to the capacitance contributions of the introduced nanofillers, increased PANI amount, and the rougher morphology due to the embedment of the nan ofillers into the PANi matrix. Different polyaniline (PANI)-based
This review mainly focuses on the recent advances in oxygen-deficient tungsten oxides from the point of atomic structures, including the forming mechanism of
Polyaniline (PANI)/tungsten oxide (WO3) nanocomposite films were fabricated by electropolymerization of aniline monomers onto WO3 coated indium tin oxide (ITO) glass slides, which were prepared by spin coating technique and followed by annealing at 500 °C for 2 h. The morphology and crystalline structure of the composite films were studied
made them attractive candidates for the fulfillment of increasing universal energy storage requirements [[14], [15], [16]]. The doping of tungsten trioxide and manganese dioxide boosts the electrochemical performance in 3D
It could also maintain a super-long energy storage time of more than 300 h through promoting the multielectron reduction of O 2 on Pt for providing trapping sites to store electrons (Li et al., 2013). Fig. 8. (a) illustrated the oxygen vacancies in the tungsten trioxide, which is clearly shown along the hydrogen treatment. Fig. 8. (b) shows the
As the best-known and extensively-studied electrochromic material, tungsten trioxide (WO 3) has drawn tremendous interest due to its low material cost, environmental benignity, dual band regulation, high optical modulation, and high chemical stability.However, these films always suffer from ion-trapping-induced degradation in
To meet the ever-growing demands over electrochemical energy storage, tungsten trioxide (WO 3) has aroused substantial attention as a promising anodic material for lithium-ion batteries due to its high theoretical capacity, abundant earth storage, and eco-friendliness.However, developing high-performance WO 3-based electrodes is
The development of high-performance electrochemical energy-storage (EES) system with superior energy and power densities is of utmost importance for effective implementation in electric vehicles (EVs). Herein, we have prepared the tungsten oxide (WO 3) nanostructures via a hydrothermal route and investigated their electrochemical
Herein, we have prepared the tungsten oxide (WO 3) nanostructures via a hydrothermal route and investigated their electrochemical energy storage properties by
The assembled EESD not only showed attractive electrochromic and energy storage performances, but also can be applied as a real-time monitoring of
Highlights. •. A self-healing electrochromic-pseudocapacitor was constructed at first time. •. The TiO 2 /WO 3 nanorod arrays exhibited excellent dual
The tungsten trioxide monohydrate (WO 3 ·H 2 O) nanosheets were directly formed on fluorine-doped tin oxide (FTO) substrates without any guidance of seed layer by a novel and quite facile one-step citric acid-assisted hydrothermal method at low temperature (90 °C). The WO 3 ·H 2 O nanosheets possess porous morphologies and
The deposition process and investigation of the physical properties of tungsten trioxide (WO Tungsten trioxide/zinc tungstate bilayers: electrochromic behaviors, energy storage and electron transfer Electrochim. Acta, 132 (2014), pp. 58-66, 10.1016/j [21] Y.
A high-performance electrochromic-energy storage device (EESD) is developed, which successfully realizes the multifunctional combination of electrochromism and energy storage by constructing tungsten trioxide monohydrate (WO 3 ·H 2 O) nanosheets and Prussian white (PW) film as asymmetric electrodes. The EESD presents
This review mainly focuses on the current progress in the development of tungsten oxide-based electrodes for energy-storage applications, primarily supercapacitors (SCs) and batteries. Tungsten is
Because energy storage and electrochromism had the same electrochemical process, the color of the ESD simultaneously changed during charging and discharging. Large-scale multifunctional electrochromic-energy storage device based on tungsten trioxide monohydrate nanosheets and prussian white. ACS Appl. Mater.
Current literature confirms that tungsten trioxide can act as the support for noble metals and itself possesses electrocatalytic activity towards hydrogen evolution. Unfortunately, the adsorption energy of the atomic hydrogen on a W-site is undesirable, which leads to the poor activity of WO 3 towards HER. The adsorption energies of
In this paper, high-performance dual-functional electrodes based on tungsten trioxide (WO3) nanostructures are developed, which successfully realize the combination of electrochromism and energy
Tungsten trioxide, WO3, is a wide bandgap semiconductor with versatile applications. It has become one of the most inves-tigated functional materials due to its unique properties, for example, electrochromism, photochromism, electrocatalysis and photocatalysis [11–13]. WO3 thin films are capable of exhibiting
As a promising novel energy storage device with fast charging-discharging rate and extremely long cycling life, electrochemical supercapacitor possesses not only higher energy density than conventional dielectric capacitors
Tungsten trioxide (WO 3) Current progress in the advancement of energy-storage devices is the most important factor that will allow the scientific community to develop resources to meet the global energy demands of the 21st century. Nanostructured materials can be used as effective electrodes for energy-storage
Tungsten trioxide (WO 3) is an abundant, versatile oxide that is widely explored for catalysis, sensing, electrochromic devices, and numerous other applications. The exploitation of WO 3 in nanosheet form provides
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