Precise design of VO2 thin films for smart windows by employing thickness dependent refractive index

TL;DR

This paper develops a method to accurately determine the thickness-dependent refractive index of VO2 thin films using theoretical models and experimental data, enabling optimized design of thermochromic smart windows.

Contribution

It introduces a collection of thickness-dependent refractive indices for VO2 films using three models, improving transmission calculations and aiding in the design of smart windows.

Findings

Enhanced transmission accuracy with thickness-dependent refractive index data

Ability to optimize VO2 film thickness for specific transmission properties

Agreement between theoretical calculations and experimental results

Abstract

Vanadium dioxide (VO2) is an adjustable refractive index material and has capability of behaving as semiconductor or conductor depending on its temperature. Such condition makes it as a material which can be employed in fabricating thermochromic smart windows. The transmission characteristics of these type of windows strongly depend on the thickness of the film. Therefore, some calculations are required to optimize the VO2 thickness. Unfortunately, refractive index of VO2 thin film is thickness dependent, therefore, in calculating the transmission of light spectrum from VO2 thin films, a unique refractive index cannot be utilized. In the present paper using three theoretical models (Lorentz-Drude oscillator, Lorentz oscillator, and Tauc-Lorentz) and employing experimental results from previous reports, we provide a collection of thickness dependent refractive index of VO2 films. More precise transmission can be achieved by using this set of refractive index data in the calculations which agree with those of experiments. These results also fairly make us capable to determine optimized film thickness for any desired transmission performance. This method is useful for design of VO2 based thermochromic smart windows.