Kinetic Study of Li<sub>x</sub>WO<sub>3</sub> Electrochromism

Nagai, Junichi; Kamimori, Tadatoshi

doi:10.1143/jjap.22.681

Cited by 50 publications

(14 citation statements)

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“…In this paper we apply this type of analysis to investigate the principal features of CVs of lithium intercalation and deintercalation in thin electrochromic films based on a-WO 3 . Nagai and Kamimori [8] also studied the implication of the underlying electrochemical mechanisms on CVs shapes, attempting to provide a simplified equivalent circuit that accounts for them. Here we show first, the determination of chemical capacitance from measurements in galvanostatic quasiequilibrium conditions.…”

Section: Introductionmentioning

confidence: 99%

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Garcı́a-Cañadas

Mora‐Seró

Fabregat‐Santiago

et al. 2004

Journal of Electroanalytical Chemistry

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Section: Introductionmentioning

confidence: 99%

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Garcı́a-Cañadas

Mora‐Seró

Fabregat‐Santiago

et al. 2004

Journal of Electroanalytical Chemistry

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“…The density of evaporated WO 3 was determined to be 6.0 ± 0.3 gm/c.c [41], [47]. Tungsten oxide films evaporated from WO 3 powder (at room temperature) have been reported to be defect compounds of the type WO 3−y , and the stoichiometry of the evaporated WO 3 thin films was reported to be ∼2.72 (O/W ratio) by many workers [from different techniques, e.g., Proton backscattering, Auger electron spectroscopy (AES) and Electron spectroscopy for chemical analysis (ESCA)] [52]- [54].…”

Section: Preparation Of Tungsten Bronze Thin Filmsmentioning

confidence: 99%

Thermo Optic Coefficients and Electronic Polarizabilities of Tungsten Bronzes Using Ellipsometry

Hussain

2019

IEEE Photonics J.

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The values of dn/dT for thermally evaporated WO 3 thin films were found to be negative either in the heating cycle (295-373 K) or in the cooling cycle (100-300 K) and were found to be of order of 10 −5 K −1. On the other hand thermo optic coefficients (TOCs: dn/dT and dk/dT values) of tungsten bronzes (H + , Li + , Na +) with different concentrations were found to be positive and negative, respectively in both the heating and cooling cycles and they were found to be in the order of 10 −4 K −1. Heating cycles show hysteresis loops of n and k for tungsten bronzes, which are good for electrochromic devices. On heating the bronzes at temperature higher than 400 K, there might be a reduction in the porosity but an irreversible disordering of hydrogen, lithium or sodium atoms could occur because of anomalous dispersions produced in the optical data. For cooling cycles, the calculated TOCs were again of the order of 10 −4 but there was an increase in dn/dT and a decrease in dk/dT values due to more amorphousness built up in the bronzes during the cooling cycles. This change in the values of TOCs for tungsten bronzes created small decrease in electronic polarizabilities (α e) which were calculated in the range from 8.003 to 8.02 × 10 −24 cm 3 in the cooling cycles.

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“…The time dependence of the coloration of amorphous WO 3 at low voltages was described in terms of a barrier for current at the WO 3 -electrolyte interface. 2,3 The coloring and bleaching processes of Li x WO 3 films were examined in short time ranges considering diffusion-limited process, 4 whereas the kinetics of electrochemical reactions in WO 3 was found to be governed by the resistance that depends on the conductivity of electrolyte, reduced forms of WO 3 and transparent conducting layers. 5 The ion transport in host electrodes was reviewed in Refs.…”

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Dynamics in Electrochromic Windows Interpreted with an Extended Logistic Model

Roldán

Romanyuk

2016

J. Electrochem. Soc.

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Complete electrochromic (EC) devices based on tungsten oxide are characterized by the chronocoulometry technique in a wide range of applied voltage and time. An empirical model is proposed to approximate the recorded charge evolution over extended periods of time required for the full coloration transition. The model is described by an analytic expression based on the logistic population growth of tungsten bronzes that are responsible for the coloration upon ion intercalation into tungsten oxide, and just four parameters characterize the dynamics of the EC device. The model is verified by fitting experimental chronocoulograms recorded from two different commercial EC windows. It is discussed how the model can be used for the description of the coloration dynamics and estimation of the coloration efficiency. Switchable smart windows based on the electrochromic (EC) technology are becoming popular in the architectural sector as they offer potential energy savings and improved visual comfort.1 One of the key parameters of the EC device is its switching speed, i.e. time required to switch between the lightest and most intensive coloration. When compared to other "switchable" technologies like suspended particle devices (SPDs) or polymer dispersed liquid crystal devices, EC windows exhibit a relatively slow switching speed, on the order of 10 -20 min for the full color transition, which hinders a fast market penetration and still remains an important topic for research and development.An EC window contains typically tungsten oxide layer (WO 3 ) as the primary EC material, which changes its color due to the potentialinduced intercalation of protons or alkali ions into the WO 3 electrode resulting in the formation of so-called tungsten bronzes. Numerous approaches and models have been proposed to investigate electrointercalation into EC materials like WO 3 . Early studies focused on the bleaching and coloring of WO 3 electrodes immersed in various liquid electrolytes. The time dependence of the coloration of amorphous WO 3 at low voltages was described in terms of a barrier for current at the WO 3 -electrolyte interface.2,3 The coloring and bleaching processes of Li x WO 3 films were examined in short time ranges considering diffusion-limited process, 4 whereas the kinetics of electrochemical reactions in WO 3 was found to be governed by the resistance that depends on the conductivity of electrolyte, reduced forms of WO 3 and transparent conducting layers. 5 The ion transport in host electrodes was reviewed in Refs. 6-9, and rigorous models of diffusion phenomena often require sophisticated numerical calculations. 9-11The current transients for potential steps during the intercalation of Li-ions in Li 1−δ CoO 2 electrodes were found by Refs. 12,13 to deviate from the theoretical predictions. Their chronoamperometric data were interpreted in terms of the cell-impedance controlled diffusion of Li-ions. The diffusion flux of intercalated species at the electrode surface limited by the interfacial charge transfer kinetics ...

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Kinetic Study of Li_xWO₃ Electrochromism

Cited by 50 publications

References 15 publications

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Thermo Optic Coefficients and Electronic Polarizabilities of Tungsten Bronzes Using Ellipsometry

Dynamics in Electrochromic Windows Interpreted with an Extended Logistic Model

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Kinetic Study of LixWO3 Electrochromism

Cited by 50 publications

References 15 publications

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Analysis of cyclic voltammograms of electrochromic a-WO3 films from voltage-dependent equilibrium capacitance measurements

Thermo Optic Coefficients and Electronic Polarizabilities of Tungsten Bronzes Using Ellipsometry

Dynamics in Electrochromic Windows Interpreted with an Extended Logistic Model

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Kinetic Study of Li_xWO₃ Electrochromism