A low-temperature synthesis of strongly thermochromic W and Sr co-doped VO2 films with a low transition temperature

TL;DR

This paper presents a low-temperature method to produce W and Sr co-doped VO2 films with enhanced thermochromic properties suitable for smart windows, achieved through reactive high-power impulse magnetron sputtering without post-deposition annealing.

Contribution

It introduces a novel low-temperature deposition technique for crystalline W and Sr co-doped VO2 films with controlled stoichiometry and improved optical properties for smart window applications.

Findings

Decreased transition temperature below 25°C due to W doping.

Significant increase in luminous transmittance with Sr doping.

Optimized film shows high luminous transmittance and solar modulation, outperforming undoped films.

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. We report low-temperature (320 degC) depositions of thermochromic V1-x-yWxSryO2 films with a thickness of 71-73 nm onto 170-175 nm thick Y-stabilized ZrO2 layers on a 1 mm thick conventional soda-lime glass. The developed deposition technique is based on reactive high-power impulse magnetron sputtering with a pulsed O2 flow feedback control allowing us to prepare crystalline W and Sr co-doped VO2 films of the required stoichiometry without any substrate bias or post-deposition annealing. The W doping of VO2 decreases the transition temperature below 25 degC, while the Sr doping of VO2 increases the integral luminous transmittance, Tlum, significantly due to widening of the visible-range optical band gap, which is consistent with lowering of the absorption coefficient of films. We present the discussion of the effect of the Sr content in the metal sublattice of VO2 on the electronic and crystal structure of V1-x-yWxSryO2 films, and on their temperature-dependent optical and electrical properties. An optimized V0.855W0.018Sr0.127O2 film exhibits a high Tlum = 56.8% and modulation of the solar energy transmittance deltaTsol = 8.3%, which are 1.50 times and 1.28 times, respectively, higher compared with those of the V0.984W0.016O2 film. The achieved results constitute an important step toward a low-temperature synthesis of large-area thermochromic VO2-based coatings for future smart-window applications, as it is easy to further increase the Tlum and deltaTsol by >6% and >3%, respectively, using a 280 nm thick top SiO2 antireflection layer.