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    Journals >Journal of Inorganic Materials >Volume 36 >Issue 2 >Page 128 > Article
    • Journal of Inorganic Materials
    • Vol. 36, Issue 2, 128 (2021)
    Electrochromic Devices Based on Tungsten Oxide and Nickel Oxide: a Review
    Xiaolan ZHONG1, Xueqing LIU1, and Xungang DIAO2、*
    Author Affiliations
  • 11. School of Physics, Beihang University, Beijing 100191, China
  • 22. School of Energy and Power Engineering, Beihang University, Beijing 100191, China
    • show less
    DOI: 10.15541/jim20200488 Cite this Article
    Xiaolan ZHONG, Xueqing LIU, Xungang DIAO. Electrochromic Devices Based on Tungsten Oxide and Nickel Oxide: a Review[J]. Journal of Inorganic Materials, 2021, 36(2): 128 Copy Citation Text show less
    Schematic diagram of the effect of trapped ions on the OCP and charge density of inserted ions[14]
    1. Schematic diagram of the effect of trapped ions on the OCP and charge density of inserted ions[14]
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    Illustration of WO3 thin films fabrication process, crystal structure and oxygen vacancy change induced by Ar/O2 atmosphere annealing[18]
    2. Illustration of WO3 thin films fabrication process, crystal structure and oxygen vacancy change induced by Ar/O2 atmosphere annealing[18]
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    Elements doped to WO3 and NiO films which researched from 2016 to 2020
    3. Elements doped to WO3 and NiO films which researched from 2016 to 2020
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    Electrochromic mechanism diagram of 2D grid-structured and plane WO3 film[36]
    4. Electrochromic mechanism diagram of 2D grid-structured and plane WO3 film[36]
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    Schematic of the crystallinity gradient in NiO film and photos of NiO film in colored and bleached state[51]
    5. Schematic of the crystallinity gradient in NiO film and photos of NiO film in colored and bleached state[51]
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    Facile preparation of aligned NiO nanotube arrays[58]
    6. Facile preparation of aligned NiO nanotube arrays[58]
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    Preparation procedures of the hierarchical-porous NiO@C film[61]
    7. Preparation procedures of the hierarchical-porous NiO@C film[61]
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    Schematic diagram of large-scale all-solid-state device structure and photograph[75]
    8. Schematic diagram of large-scale all-solid-state device structure and photograph[75]
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    Structural schematic diagram of ECD
    9. Structural schematic diagram of ECD
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    YearDevice structuretc/stb/sCE/(cm2·C-1)ΔT/%CyclesRef.
    2016ITO/NiOx/ZrO2:H/WO3/ITO116108-65.22000[72]
    2016ITO/NiOx/Ta2O5:H/WO3/ITO---60-[76]
    2016ITO/WO3/LiClO4-PC-PMMA/NiOx/ITO4.51.7-51.750000[77]
    2016Glass/ITO/WO3/LiNbO3/NiOx/ITO4525-65-[78]
    2016ITO/NiOx:Ti/PVB(Li+)/WO3/ITO4.43.29660-[79]
    2017Glass/ITO/WO3/PVB-GPEF/Ni1-xO/ITO/Glass9.516175.3465.83000[80]
    2017Glass /ITO/NiOx/electrolyte/WO3/ITO72-70300[81]
    2017Glass /ITO/NiO/Si3N4/LiNbO3/Si3N4/WO3/ITO---43-[82]
    2017ITO/NiO/Ta2O5/LiNbO3/WO3/ITO---34-[83]
    2018Glass/ITO/NiO/Si3N4/LixMgyN/WO3/ITO--77401000[84]
    2018Glass/ITO/WO3/Li2.5TaOx/NiO/ITO30306340300[71]
    2018FTO/WO3/gel polymer electrolyte/NiO/FTO1.22.6-43.8120000[85]
    2018Glass/ITO/WO3:H/Ta2O5/NiOx/ITO--24.342300[86]
    2018Glass/ITO/WO3/LiPON/NiO/ITO---40-[74]
    2018Glass/ITO/LixNiOy/LiTaO3/WO3/ITO133.542407000[87]
    2018ITO/NiOx/Ta2O5/LiNbO3/Ta2O5/WO3/ITO--9852.510000[88]
    2018ITO/NiO/ZrO2/LiNbO3/WO3/ITO--24.353-[89]
    2018ITO/NiO/Ta2O5/LiNbO3/WO3/ITO/Glass107-71.7-[90]
    2019Glass/IAI/NiOx/LiClO4-PC-PMMA/WO3/IAI/Glass2.252.0231.755-[62]
    2019ITO/NiOx/LixAlOz/WO3/ITO5.72.276.4574.410000[75]
    2019ITO/WO3-Nb2O5/Nb2O5/NiVOx/ITO70.7-3330000[91]
    2019ITO/WO3/LiClO4-PC-PMMA/NiO/ITO3.21.1130.8451000[92]
    2019ITO/NiOx/Ta2O5/LiNbO3/Ta2O5/WO3/ITO18.49.5-55.22500[93]
    2019ITO/NiOx/Ta2O5/WO3/ITO132-70.9-[94]
    2020Glass /ITO/WO3/LiF/NiO/ITO9.6488.558.9450[73]
    2020ITO/WO3/Gelatin/NiO/ITO105060.3843.35-[70]
    2020ITO/Li-NiO/Li-WO3/ITO8.61.787.5321000[95]
    2020ITO/WO3/LiClO4-PC-PMMA-ACN/NiO/ITO1.21.524351.2720000[96]
    2020ITO/WO3/LiNbO3/Al-LiNiOx/ITO17.94.1-445000[97]
    Table 1. Comparison of structure and performance of ECDs based on WO3 and NiO films researched from 2016 to 2020
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    Xiaolan ZHONG, Xueqing LIU, Xungang DIAO. Electrochromic Devices Based on Tungsten Oxide and Nickel Oxide: a Review[J]. Journal of Inorganic Materials, 2021, 36(2): 128
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