Title
Phase separation of VO2 and SiO2 on SiO2-Coated float glass yields robust thermochromic coating with unrivalled optical properties
Author
Yeung, C.P.K.
Habets, R.
Leufkens, L.
Colberts, F.
Stout, K.
Verheijen, M.
Vroon, Z.
Mann, D.
Buskens, P.
Publication year
2021
Abstract
Vanadium dioxide displays thermochromic properties based on its structural phase transition from monoclinic VO2 (M) to rutile VO2 (R) and vice versa, and the accompanying reversible metal-insulator transition. We developed a single layer coating comprising VO2 (M) and SiO2. We applied the coating from an alcoholic solution comprising vanadium(IV) oxalate complex and pre-oligomerized tetra ethoxy silane to SiO2-coated float glass using dip coating, and thermally annealed the dried xerocoat in a two-step process. The addition of SiO2 as coating matrix resulted in non-scattering coatings with low surface roughness and random distribution of VO2 nanodomains (≤200 nm). Furthermore, the formation of the coating, comprising a phase separation yielding SiO2 and VO2 nanodomains during the thermal anneal, was studied in detail. The coating displays unrivalled optical properties, combining high visible light transmission Tvis > 60% and large solar modulation ΔTsol ≥ 10%. When applied in insulating glass units, the coating has a positive impact on energy savings for heating and cooling of buildings in intermediate climates, which we demonstrated through building energy simulations. For a typical house in the Netherlands, energy savings up to 24% were obtained. In addition, we demonstrate a coating stability comparable to current energy-efficient window coatings during processing into and in insulating glass units through (accelerated) life time tests.
Subject
Building energy simulations
Coating
Energy-efficiency
Silica
Smart window
Sol-gel
Thermochromic
Vanadium dioxide
To reference this document use:
http://resolver.tudelft.nl/uuid:bae91633-137b-4e3b-b07b-1fbea1a7fd0c
DOI
https://doi.org/10.1016/j.solmat.2021.111238
TNO identifier
957093
Publisher
Elsevier B.V.
ISSN
0927-0248
Source
Solar Energy Materials and Solar Cells, 230 (230)
Document type
article