Affordable Smart Windows with Dual‐Functionality: Electrochromic Color Switching and Charge Storage
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[1] Jinxing Chen,et al. Dual-Function Self-Powered Electrochromic Batteries with Energy Storage and Display Enabled by Potential Difference , 2022, ACS Energy Letters.
[2] Pooi See Lee,et al. Pseudocapacitive and Dual-functional Electrochromic Zn Batteries , 2022, Materials Today Energy.
[3] Ashutosh K. Singh,et al. Large‐Area Fabrication of High Performing, Flexible, Transparent Conducting Electrodes Using Screen Printing and Spray Coating Techniques , 2021, Advanced Materials Technologies.
[4] Yanhong Tian,et al. Robust Cu-Au alloy nanowires flexible transparent electrode for asymmetric electrochromic energy storage device , 2021 .
[5] Kui Shen,et al. Robust non-complementary electrochromic device based on WO3 film and CoS catalytic counter electrode with TMTU/TMFDS2+ redox couple , 2021 .
[6] Kent J. Griffith,et al. Tunable Intracrystal Cavity in Tungsten Bronze‐Like Bimetallic Oxides for Electrochromic Energy Storage , 2021, Advanced Energy Materials.
[7] Jian-Wei Liu,et al. Self-Powered Flexible Electrochromic Smart Window. , 2021, Nano letters.
[8] Xiuqiang Li,et al. Ultra-Wideband Transparent Conductive Electrode for Electrochromic Synergistic Solar and Radiative Heat Management , 2021, ACS Energy Letters.
[9] S. Hoseinzadeh,et al. Magnetron sputtering technique for analyzing the influence of RF sputtering power on microstructural surface morphology of aluminum thin films deposited on SiO2/Si substrates , 2021, Applied Physics A.
[10] Kai-Li Tao,et al. Boosting charge-transfer kinetics and cyclic stability of complementary WO3–NiO electrochromic devices via SnOx interfacial layer , 2021 .
[11] Hongliang Zhang,et al. Long-term-stable WO3-PB complementary electrochromic devices , 2021 .
[12] Ashutosh K. Singh,et al. Scalable Fabrication of Scratch-Proof Transparent Al/F-SnO2 Hybrid Electrodes with Unusual Thermal and Environmental Stability. , 2020, ACS applied materials & interfaces.
[13] G. Niklasson,et al. Electrochromic tungsten oxide films prepared by sputtering: Optimizing cycling durability by judicious choice of deposition parameters , 2020 .
[14] Caroline Sunyong Lee,et al. Crack-free fabrication of Prussian blue-based blending film for the dramatic enhancement of dual electrochromic device , 2020 .
[15] G. U. Kulkarni,et al. Innovative Approach to Photo-Chemiresistive Sensing Technology: Surface-Fluorinated SnO2 for VOC Detection. , 2020, ACS applied materials & interfaces.
[16] Po-Wen Chen,et al. Fast response of complementary electrochromic device based on WO3/NiO electrodes , 2020, Scientific Reports.
[17] X. Weng,et al. A high-performance electrochromic device assembled with hexagonal WO3 and NiO/PB composite nanosheet electrodes towards energy storage smart window , 2020, Solar Energy Materials and Solar Cells.
[18] H. Bailung,et al. Synthesis and Characterization of Oxygen Vacancy Induced Narrow Bandgap Tungsten Oxide (WO3−x) Nanoparticles by Plasma Discharge in Liquid and Its Photocatalytic Activity , 2020, Plasma Chemistry and Plasma Processing.
[19] Y. Mai,et al. Reactively sputtered WO3 thin films for the application in all thin film electrochromic devices , 2019 .
[20] G. U. Kulkarni,et al. Patterned Cu-Mesh-Based Transparent and Wearable Touch Panel for Tactile, Proximity, Pressure, and Temperature Sensing , 2019, ACS Applied Electronic Materials.
[21] Haekyoung Kim,et al. Flexible electrochromic device with simple solution processed stable silver , 2019, Synthetic Metals.
[22] Y. Gogotsi,et al. MXene-conducting polymer electrochromic microsupercapacitors , 2019, Energy Storage Materials.
[23] Jinmin Wang,et al. Optimized properties of innovative ElectroChromic Device using ITO / Ag / ITO electrodes , 2019, Electrochimica Acta.
[24] M. Bilek,et al. Transparent Conductive Dielectric-Metal-Dielectric Structures for Electrochromic Applications Fabricated by High-Power Impulse Magnetron Sputtering. , 2019, ACS applied materials & interfaces.
[25] Y. Gogotsi,et al. Electrochromic Effect in Titanium Carbide MXene Thin Films Produced by Dip‐Coating , 2019, Advanced Functional Materials.
[26] S. Nahm,et al. VO2/WO3-Based Hybrid Smart Windows with Thermochromic and Electrochromic Properties , 2019, ACS Sustainable Chemistry & Engineering.
[27] A. Subrahmanyam,et al. Electrochromic device with magnetron sputtered tungsten oxide (WO3) and nafion membrane: performance with varying tungsten oxide thickness- a report , 2019, Materials Research Express.
[28] Se Hyun Kim,et al. Dual-Function Electrochromic Supercapacitors Displaying Real-Time Capacity in Color. , 2018, ACS applied materials & interfaces.
[29] Shuliang Zou,et al. Effect of roughness of substrate and sputtering power on the properties of TiN coatings deposited by magnetron sputtering for ATF , 2018, Journal of Nuclear Materials.
[30] Yang Zhou,et al. Emerging Thermal‐Responsive Materials and Integrated Techniques Targeting the Energy‐Efficient Smart Window Application , 2018 .
[31] Yu Xiao,et al. Dynamic behaviors of inorganic all-solid-state electrochromic device: Role of potential , 2018 .
[32] Caroline Sunyong Lee,et al. Fabrication of transparent conductive tri-composite film for electrochromic application , 2017 .
[33] Hongzhi Wang,et al. High-performance complementary electrochromic device based on WO3·0.33H2O/PEDOT and prussian blue electrodes , 2017 .
[34] Mohd Fadzil Ain,et al. Structural, surface morphology and optical properties of sputter-coated CaCu3Ti4O12 thin film: Influence of RF magnetron sputtering power , 2017 .
[35] Anilesh Kumar,et al. ITO-Free Solution-Processed Flexible Electrochromic Devices Based on PEDOT:PSS as Transparent Conducting Electrode. , 2017, ACS applied materials & interfaces.
[36] Pooi See Lee,et al. Highly Transparent Conducting Nanopaper for Solid State Foldable Electrochromic Devices. , 2016, Small.
[37] C. Li,et al. Reactive Sputter Deposition of WO3/Ag/WO3 Film for Indium Tin Oxide (ITO)-Free Electrochromic Devices. , 2016, ACS applied materials & interfaces.
[38] W. Cui,et al. Experimental investigation on dwell-fatigue property of Ti–6Al–4V ELI used in deep-sea manned cabin , 2015 .
[39] M. Maaza,et al. Electronic thermal conductivity, thermoelectric properties and supercapacitive behaviour of conjugated polymer nanocomposite (polyaniline-WO3) thin film , 2015 .
[40] O. Hussain,et al. Structural, optical and electrochromic properties of RF magnetron sputtered WO3 thin films , 2014 .
[41] Cheol-Min Yang,et al. Flexible electrochromic films based on CVD-graphene electrodes , 2014, Nanotechnology.
[42] C. Labrugère,et al. Synthesis and characterization of WO3 thin films by surfactant assisted spray pyrolysis for electrochromic applications , 2013 .
[43] Nobuto Oka,et al. Reactive-gas-flow sputter deposition of amorphous WO3 films for electrochromic devices , 2013 .
[44] D. Jan,et al. Bond and electrochromic properties of WO3 films deposited with horizontal DC, pulsed DC, and RF sputtering , 2013 .
[45] S. Mali,et al. Transmission attenuation and chromic contrast characterization of R.F. sputtered WO3 thin films for electrochromic device applications , 2012 .
[46] M. Deepa,et al. Poly(3,4-ethylenedioxythiophene)-multiwalled carbon nanotube composite films: structure-directed amplified electrochromic response and improved redox activity. , 2009, The journal of physical chemistry. B.
[47] Horng-Hwa Lu,et al. Effects of oxygen contents on the electrochromic properties of tungsten oxide films prepared by reactive magnetron sputtering , 2008 .
[48] Jinmin Wang,et al. Synthesis, Assembly, and Electrochromic Properties of Uniform Crystalline WO3 Nanorods , 2008 .
[49] M. Wong,et al. Structures and electrochromic properties of tungsten oxide films prepared by magnetron sputtering , 2005 .
[50] C. Guillén,et al. Comparison study of ITO thin films deposited by sputtering at room temperature onto polymer and glass substrates , 2005 .
[51] Chuan-fu Cheng,et al. Effects of sputtering power on the properties of ZnO:Ga films deposited by r.f. magnetron-sputtering at low temperature , 2005 .
[52] C. E. Tracy,et al. Electrochromic coloration efficiency of a-WO3−y thin films as a function of oxygen deficiency , 1999 .
[53] I. Petrov,et al. High‐flux low‐energy (≂20 eV) N+2 ion irradiation during TiN deposition by reactive magnetron sputtering: Effects on microstructure and preferred orientation , 1995 .
[54] B. Zou,et al. Boosting the Zn2+-based electrochromic properties of tungsten oxide through morphology control , 2021 .
[55] Claes-Göran Granqvist,et al. Electrochromic materials and devices for energy efficiency and human comfort in buildings: A critical review , 2018 .
[56] D. Depla,et al. Reactive Sputter Deposition , 2008 .