Abstract

The reversible semiconductor-to-metal transition of vanadium dioxide (VO2) makes VO2-based coatings a promising candidate for thermochromic smart windows, reducing the energy consumption of buildings. This paper deals with maximizing the application potential of these coatings in terms of their performance, an industry-friendly preparation technique, and an industrially relevant substrate. We present a scalable sputter deposition technique for the preparation of strongly thermochromic ZrO2/V0.984W0.016O2/ZrO2 coatings on ultrathin flexible glass and standard glass at a relatively low substrate surface temperature (330 °C) and without any substrate bias voltage. The V0.984W0.016O2 layers were deposited by a controlled high-power impulse magnetron sputtering of a V target, combined with a simultaneous pulsed dc magnetron sputtering of a W target. We explain the fundamental principles of this technique using the discharge characteristics measured for both discharges. We characterize the coating structure (X-ray diffraction) and a wide range of optical properties (spectrophotometry and spectroscopic ellipsometry). We find that the coatings combine a transition temperature of 22 °C, a luminous transmittance approaching 50%, a modulation of the solar energy transmittance over 10% and a temperature-independent color. The results in general, and the successful transfer from a standard glass to the ultrathin flexible glass in particular, are crucial for future applications of the coatings on smart windows.

Highlights

  • Global warming causes numerous problems in human society and drives a focus on energy-saving materials

  • We have presented and explained a scalable sputter deposition technique for the preparation of strongly thermochromic ZrO2 /V0.984 W0.016 O2 /ZrO2 coatings on ultrathin flexible glass (FG) and standard soda-lime glass (SLG)

  • The V0.984 W0.016 O2 layers were deposited by a controlled high-power impulse magnetron sputtering (HiPIMS) of a V target, combined with a simultaneous pulsed dc magnetron sputtering of a W target

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Summary

Introduction

Global warming causes numerous problems in human society and drives a focus on energy-saving materials. It is evident that energy-saving smart windows with adjustable throughput of solar energy and visible light can lower the energy expenditure. Such windows could incorporate chromogenic materials, in particular those with thermochromic and electrochromic properties [3]. VO2 (M1) semiconductive phase to a high-temperature tetragonal VO2 (R) metallic phase at a transition temperature (Ttr ) of approximately 68 ◦ C for the bulk material [4]. The abrupt decrease of infrared transmittance without attenuation of luminous transmittance in the metallic state makes VO2 -based coatings a promising candidate for thermochromic smart windows reducing the energy consumption of buildings

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