Abstract
The aim of thermochromic window coatings is to reduce the energy consumption in the built environment by passively switching between a high solar transmitting state at low temperatures and low solar transmitting state at high temperatures. Previous studies have highlighted the negative impact of phase transition hysteresis on the performance of reflection based thermochromic films. However in the literature, the best reported results have depended on vanadium dioxide nanoparticle composites and anti-reflective structures that modulate light via changes in absorption rather than reflection. In light of these factors, this work aims to demonstrate theoretically, how the effects of phase transition hysteresis and gradient differ between absorbing and non-absorbing thermochromic films. To quantify and compare the performance of films with different transition characteristics, we define a metric based on the varying net energy flux through the window over the course of a year, including thermal energy re-radiated into the building from the film. Specifically, and importantly for the field, we demonstrate that a pseudo-photochromic effect in absorbing thermochromic films mitigates the detrimental effects of phase transition hysteresis and gradient that have been reported for reflection based thermochromic films. We find that for moderate hysteresis widths of 15 °C, the performance of the non-absorbing case drops to ~60% of its initial value whilst the performance of the absorbing film only drops to ~95%. As a result we find that the absorbing case outperforms the non-absorbing case when hysteresis widths are greater than 8 °C.
Highlights
Thermochromic window coatings have long held the promise of reducing heating and cooling energy loads within the built environment by passively modulating the transmission of solar radiation, switching between a high solar transmitting state at low temperatures and low solar transmitting state at high temperatures[1,2]
The detrimental effects of phase transition hysteresis on performance that are apparent in non-absorbing thermochromic coatings are greatly mitigated in absorbing coatings due to an additional dependence of transition state on the intensity of incident solar radiation
The results presented in this work can be seen as encouraging to all those pursuing vanadium dioxide window coatings for passive solar control applications
Summary
Thermochromic window coatings have long held the promise of reducing heating and cooling energy loads within the built environment by passively modulating the transmission of solar radiation, switching between a high solar transmitting state at low temperatures and low solar transmitting state at high temperatures[1,2]. The performance of state-of-the-art thermochromic coatings depends largely on the use of anti-reflective structures[8,9,10,11] or nanoparticles[12,13,14,15,16] where modulation of solar transmittance is achieved primarily through changes in absorption rather than reflection, and in the case of nanoparticles, where coatings exhibit significant hysteresis and gradient widths due to the small non-uniform domain sizes of the phase change components[13,14] In light of these factors, this work aims to demonstrate for the first time, how the effects of transition gradient and hysteresis differ between absorbing and non-absorbing thermochromic coatings. Is found that the negative effects of transition gradient and hysteresis widths are greatly mitigated as a result of solar absorption
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