Thermochromic behavior of VO 2 /polymer nanocomposites for energy saving coatings

Abstract

Vanadium dioxide (VO 2 ) is a well-known thermochromic material that can potentially be used as a smart coating on glazing systems in order to regulate the internal temperature of buildings. Most growth techniques for VO 2 demand high temperatures (>250 °C), making it impossible to comply with flexible (polymeric) substrates. To overcome this problem, hydrothermally synthesized VO 2 particles may be dispersed in an appropriate matrix, leading to a thermochromic coating that can be applied on a substrate at a low temperature (<100 °C). In this work, we reported on the thermochromic properties of a VO 2 /Poly-Vinyl-Pyrrolidone (PVP) nanocomposite. More specifically, a fixed amount of VO 2 particles was dispersed in different PVP quantities forming hybrids of various VO 2 /PVP molar ratios which were deposited as films on fused silica glass substrates by utilizing the drop-casting method. The crystallite size was calculated and found to be 35 nm, almost independent of the PVP concentration. As far as the thermochromic characteristics are concerned, the molar ratio of the VO 2 /PVP nanocomposite producing VO 2 films with the optimum thermochromic properties was 0.8. These films exhibited integral solar transmittance modulation (overall wavelengths) ΔTr sol = 0.35%-1.7%, infrared (IR) switching at 2000 nm ΔTr IR = 10%, visible transmittance at 550 nm Tr Vis = 38%, critical transition temperature T C = 66.8 °C, and width of transmittance hysteresis loop ΔT C = 6.8 °C. Moreover, the critical transition temperature was observed to slightly shift depending on the VO 2 /PVP molar ratio.