Citation: Murillo-Quirós, N.;

Vega-Garita, V.; Carmona-Calvo, A.;

Rojas-González, E.A.; Starbird-Perez,

R.; Avendaño-Soto, E. Toward

Thermochromic VO2 Nanoparticles

Polymer Films Based Smart Windows

Designed for Tropical Climates.

Polymers 2022, 14, 4250. https://

doi.org/10.3390/polym14194250

Academic Editor:

Arunas Ramanavicius

Received: 19 August 2022

Accepted: 26 September 2022

Published: 10 October 2022

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polymers

Review

Toward Thermochromic VO2 Nanoparticles Polymer Films
Based Smart Windows Designed for Tropical Climates
Natalia Murillo-Quirós 1,2,*, Victor Vega-Garita 1,3 , Antony Carmona-Calvo 1, Edgar A. Rojas-González 2,4 ,
Ricardo Starbird-Perez 2,5 and Esteban Avendaño-Soto 2,4,*

1 Escuela de Física, Instituto Tecnológico de Costa Rica, Cartago 30101, Costa Rica
2 Centro de Investigación en Ciencia e Ingeniería de Materiales (CICIMA), Universidad de Costa Rica,

San Pedro 11501-2060, Costa Rica
3 Escuela de Ingeniería Eléctrica, Universidad de Costa Rica, San Pedro 11501-2060, Costa Rica
4 Escuela de Física, Universidad de Costa Rica, San Pedro 11501-2060, Costa Rica
5 Escuela de Química, Instituto Tecnológico de Costa Rica, Cartago 30101, Costa Rica
* Correspondence: nmurillo@itcr.ac.cr (N.M.-Q.); esteban.avendanosoto@ucr.ac.cr (E.A.-S.)

Abstract: Thermochromic smart windows have been extensively investigated due to two main
benefits: first, the comfort for people in a room through avoiding high temperatures resulting from
solar heating while taking advantage of the visible light, and second, the energy efficiency saving
offered by using those systems. Vanadium dioxide (VO2) is one of the most used materials in the
development of thermochromic devices. The countries located in the tropics show little use of these
technologies, although studies indicate that due to their characteristics of solar illumination and
temperature, they could benefit greatly. To optimize and achieve maximum benefit, it is necessary
to design a window that adjusts to tropical conditions and at the same time remains affordable for
extensive implementation. VO2 nanoparticles embedded in polymeric matrices are an option, but
improvements are required by means of studying different particle sizes, dopants and polymeric
matrices. The purpose of this review is to analyze what has been regarding toward the fabrication
of smart windows based on VO2 embedded in polymeric matrices for tropical areas and provide a
proposal for what this device must comply with to contribute to these specific climatic needs.

Keywords: smart windows; thermochromic; tropics; vanadium dioxide; nanoparticles; polymeric matrix

1. Introduction

Thermochromic smart coatings have emerged as an alternative regarding energy-
efficient buildings [1,2]. Windows are known as the most energy-inefficient components
of buildings [3,4], since they allow both the entrance and exit of energy. Thermochromic
smart windows can modulate near-infrared radiation, switching from a transmissive state
to an opaque state in response to the environmental temperature from low to high [2,5]
(see Figure 1), with no extra stimuli required, leading to lower energy consumption.

Vanadium dioxide (VO2) is the most widely studied and promising thermochromic
material [3,6], being employed as thin film [7,8], nanocomposite, micro-composite and in
other structures such as grids or biomimetic designs [9]. VO2 shows a reversible first-order
phase transition, from a semiconductor monoclinic structure (M) to a metallic rutile-like
tetragonal structure (R) when the critical temperature is reached at ca. 68 ◦C [10,11]. This
semiconductor to metal phase change causes a decrease in the electric resistivity and
an important increase in the reflectance of the infrared spectrum in the material, with
slight changes regarding the visible range of the electromagnetic spectrum [12]. Different
crystalline phases have been reported for VO2; yet, only the M and R phases show a total
reversible semiconductor to metal transformation [13]. It has been found that one way of
changing the critical temperature is by doping the VO2. The effect on the system varies
according to the doping element; having the possibility to vary the transition temperature

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Polymers 2022, 14, 4250 2 of 18

allows as a consequence to manipulate the temperature in which the system avoids the
transmittance of the infrared spectrum [14]. Tungsten (W) is the element that tailors the best
system’s transition temperature to ambient values, it reduces the transition temperature by
the rate by 20–26 ◦C per wt. % [15].

Polymers 2022, 14, x FOR PEER REVIEW  2 of 19 
 

 

 
(a) 

 
(b) 

   

Figure 1. Schematic operation of a smart thermochromic window: (a) Below transition tempera‐

ture, (b) Above transition temperature. 

Vanadium dioxide (VO2) is the most widely studied and promising thermochromic 

material [3,6], being employed as thin film [7,8], nanocomposite, micro‐composite and in 

other structures such as grids or biomimetic designs [9]. VO2 shows a reversible first‐order 

phase transition, from a semiconductor monoclinic structure (M) to a metallic rutile‐like 

tetragonal structure (R) when the critical temperature is reached at ca. 68 °C [10,11]. This 

semiconductor to metal phase change causes a decrease in the electric resistivity and an 

important increase in the reflectance of the infrared spectrum in the material, with slight 

changes regarding the visible range of the electromagnetic spectrum [12]. Different crys‐

talline phases have been reported for VO2; yet, only the M and R phases show a total re‐

versible semiconductor to metal transformation [13]. It has been found that one way of 

changing the critical temperature is by doping the VO2. The effect on the system varies 

according to the doping element; having the possibility to vary the transition temperature 

allows as a consequence to manipulate the temperature in which the system avoids the 

transmittance of the infrared spectrum [14]. Tungsten (W) is the element that tailors the 

best system’s transition temperature to ambient values, it reduces the transition tempera‐

ture by the rate by 20–26 °C per wt. % [15]. 

VO2 coating for smart windows is achieved by sputtering, vapor deposition, ion im‐

plantation and similar processes based on vanadium solutions. A disadvantage of these 

methods is their need for high temperatures (around 500 °C) and rigorous processing con‐

ditions; those limitations complicate their scalability. A solution that requires much lower 

temperatures and less controlled conditions is the synthesis of powdered VO2 (M) and its 

further dispersion into a polymeric matrix and then producing films by coating a substrate 

[16]. 

Hydrothermal synthesis is a common pathway for producing metallic oxides. It ba‐

sically consists of generating a chemical reaction on an aqueous medium to precipitate 

VO2 nanoparticles [17–19]. The production of nanoparticles by the hydrothermal method 

is particularly convenient over other synthesis routes because its final powdered appear‐

ance, as will be discussed later, may be added to polymeric films. 

To apply it to a surface, such as glass, the powder must be integrated into a polymeric 

matrix, maintaining the thermochromic properties of VO2. The choice of polymer is fun‐

damental to the design of an intelligent window because, in addition to encapsulating the 

VO2 particles, it must have remarkable adherence to the substrate, transparency to visible 

light and must keep these properties during the lifetime of the window. Thus, the polymer 

choices made by different groups and their respective considerations are reviewed. 

Many of the already mentioned characteristics of VO2 have demonstrated its poten‐

tial in the design of smarts windows; namely, among thermochromic materials, its transi‐

tion temperature, 68 °C, is the closest to room temperature, and it can easily be changed 

by doping, so it is possible to design a tunable selective modulator of infrared radiation. 

Figure 1. Schematic operation of a smart thermochromic window: (a) Below transition temperature,
(b) Above transition temperature.

VO2 coating for smart windows is achieved by sputtering, vapor deposition, ion
implantation and similar processes based on vanadium solutions. A disadvantage of these
methods is their need for high temperatures (around 500 ◦C) and rigorous processing
conditions; those limitations complicate their scalability. A solution that requires much
lower temperatures and less controlled conditions is the synthesis of powdered VO2 (M)
and its further dispersion into a polymeric matrix and then producing films by coating a
substrate [16].

Hydrothermal synthesis is a common pathway for producing metallic oxides. It
basically consists of generating a chemical reaction on an aqueous medium to precipitate
VO2 nanoparticles [17–19]. The production of nanoparticles by the hydrothermal method is
particularly convenient over other synthesis routes because its final powdered appearance,
as will be discussed later, may be added to polymeric films.

To apply it to a surface, such as glass, the powder must be integrated into a polymeric
matrix, maintaining the thermochromic properties of VO2. The choice of polymer is
fundamental to the design of an intelligent window because, in addition to encapsulating
the VO2 particles, it must have remarkable adherence to the substrate, transparency to
visible light and must keep these properties during the lifetime of the window. Thus, the
polymer choices made by different groups and their respective considerations are reviewed.

Many of the already mentioned characteristics of VO2 have demonstrated its potential
in the design of smarts windows; namely, among thermochromic materials, its transition
temperature, 68 ◦C, is the closest to room temperature, and it can easily be changed by
doping, so it is possible to design a tunable selective modulator of infrared radiation.
In addition, the phase transition of VO2 is reversible and its manufacture is simple and
inexpensive [14]. Still, some issues need to be resolved to offer it as a commercial solution.

Chang et al. point out the challenges in production of smart windows based on
VO2, such as an unfavorable brownish-yellow color of the VO2 film, the still desirable
improvement in optical properties to obtain better light and solar transmittance, the ability
to guarantee the stability of thermochromic VO2 over time and deciding which approach is
the best route for industrial production, given that, currently, the manufacturing methods
are maintained at a laboratory scale [2]. As an inorganic thermochromic material, VO2 is
toxic; therefore, in order to use it, it must be covered, so that people or pets do not touch it.
The integration of composites to coat (core–shell) VO2 and form nanostructures, the design
of multilayer films and surface treatments are presented as possible solutions to explore,
not only to overcome the indicated obstacles but also to add functions to the windows,
such as self-cleaning or hydrophilicity [20].



Polymers 2022, 14, 4250 3 of 18

Tropical countries have warm temperatures during the whole year, and those are rising
due to climate change [21,22]. The data on thermochromic windows for hot climates showed
that smart glazing can be effective in tropical regions even as skylights or sunroofs [23].
Moreover, it has been stated that in warmer areas, a lower transition temperature (around
room temperature) leads to better energy savings than in places with predominantly cold
weather [12,24,25]. Even so, the design of a thermochromic window specifically adjusted
to the needs of the tropics has not been currently reported.

The aim of this work is to provide a systematic review of the progress made in the
design of thermochromic smart windows based on VO2 designed for the tropics. This
analysis is covered in Section 1, an introduction to smart windows based on VO2 and the
tropical conditions that make them ideal for these devices. Section 2 describes in detail
the location and climate of the tropics and reviews the research conducted to control the
light and temperature conditions inside the buildings constructed in these areas. Section 3
describes the literature associated with the design of VO2-based smart windows, from the
choice of the synthesis process to the integration of VO2 in polymeric matrices for glazing
application. Section 4 proposes an ideal device, which, based on the research conducted so
far, will meet the requirements of an enclosure built in a tropical climate. Finally, Section 5
presents the main conclusions reached throughout this review. This work summarizes the
inherent thermochromic properties of VO2 in the selective modulation of infrared radiation
transmission without changing the visible electromagnetic spectrum, specifically to design
a smart window for tropical weather conditions. This device should respond gradually to
environmental conditions through manipulation of the VO2 transition temperature using
different doping percentages, so that the inhabitants of tropical structures benefit from the
comfort and energy efficiency that these devices may provide.

2. Research on Glazing in the Tropics
2.1. Geographical and Climatic Situation

The tropical zone extends from latitudes of 10 to 23◦ (see Figure 2). It is characterized by
high rainy rates throughout the year. Its geographical position provides a large amount of
solar radiation (nearly 12 h of light throughout the year), which results in high temperature
and high level of relative humidity. Tropical regions differ markedly from ones extending
from about 35 to 60◦ latitude, including most of Europe and North America [26].

Polymers 2022, 14, x FOR PEER REVIEW  4 of 19 
 

 

 

Figure 2. Geographical areas included in the tropics (red lines) and Equator (blue line). 

The United Nations is far from achieving its Sustainable Development Goal to “en‐

sure access to affordable, reliable, sustainable and modern energy for all” by 2030 [27], 

especially  in undeveloped countries. Low energy consumption  technologies are key  to 

taking advantage of the natural resources in tropical regions. 

Costa Rica  is widely recognized as a renewable‐energy‐based country  [28], with a 

potential need for advanced technological products in the solar area [29]. It is located 9.6° 

north of the equator, this geographical position means that the country has warm temper‐

atures throughout the year. According to the “Effects of Climate Change on Agriculture” 

study by ECLAC, the average annual temperature in Costa Rica had a notable increase in 

the mid‐1990s, and since then, although it has dropped, it has not returned to the historical 

levels prior to this rise. The meteorological models carried out by researchers foresee sce‐

narios of temperature increases for the remainder of this century [30]. 

Therefore, when thinking about the well‐being of the users of tropical houses, there 

are two major concerns—cooling the space and visual comfort, which means taking ad‐

vantage of  the many hours of natural  light  that  tropic geographical position provides. 

Most studies of energy efficiency for coatings, both in terms of the theoretical and experi‐

mental modeling, pertain to the northern hemisphere with a latitude of 23° [31], which 

delimits the tropical zone and beyond. However, there is a consensus that thermochromic 

windows achieve better performance in hot and warm climates than in cold ones [24,31]. 

Therefore, it is worth delving into the research on windows designed for the tropical cli‐

mate. 

2.2. Cooling Spaces Using Material Properties 

Analyzing the publications that offered solutions to regulate the temperature using 

and even improving the conditions of natural lighting in a room, some authors have ex‐

plored solutions  that do not necessarily apply smart windows. For example, Edmonds 

and Greenup described windows that can be opened, providing natural ventilation, and 

integrating devices such as light guiding shades. They are basically shelves with opaque 

and translucent areas that are placed on the outside of a window with different inclina‐

tions to cover and redirect the solar lighting to the interior of the room. The researchers 

also mention the use of angle‐selective glazing for radiant heat control [26]. It is worth 

mentioning that these resources can be useful in subtropical zones (ranging from 23° to 

35° degrees of latitude, north or south), since they take advantage of the sun’s inclination 

with respect to the zenith, but at latitudes close to the equator, the sun is very vertical all 

year round, so these devices are not very useful. 

Figure 2. Geographical areas included in the tropics (red lines) and Equator (blue line).

The United Nations is far from achieving its Sustainable Development Goal to “ensure
access to affordable, reliable, sustainable and modern energy for all” by 2030 [27], espe-
cially in undeveloped countries. Low energy consumption technologies are key to taking
advantage of the natural resources in tropical regions.



Polymers 2022, 14, 4250 4 of 18

Costa Rica is widely recognized as a renewable-energy-based country [28], with a
potential need for advanced technological products in the solar area [29]. It is located
9.6◦ north of the equator, this geographical position means that the country has warm
temperatures throughout the year. According to the “Effects of Climate Change on Agri-
culture” study by ECLAC, the average annual temperature in Costa Rica had a notable
increase in the mid-1990s, and since then, although it has dropped, it has not returned to
the historical levels prior to this rise. The meteorological models carried out by researchers
foresee scenarios of temperature increases for the remainder of this century [30].

Therefore, when thinking about the well-being of the users of tropical houses, there are
two major concerns—cooling the space and visual comfort, which means taking advantage
of the many hours of natural light that tropic geographical position provides. Most studies
of energy efficiency for coatings, both in terms of the theoretical and experimental modeling,
pertain to the northern hemisphere with a latitude of 23◦ [31], which delimits the tropical
zone and beyond. However, there is a consensus that thermochromic windows achieve
better performance in hot and warm climates than in cold ones [24,31]. Therefore, it is
worth delving into the research on windows designed for the tropical climate.

2.2. Cooling Spaces Using Material Properties

Analyzing the publications that offered solutions to regulate the temperature using
and even improving the conditions of natural lighting in a room, some authors have ex-
plored solutions that do not necessarily apply smart windows. For example, Edmonds
and Greenup described windows that can be opened, providing natural ventilation, and
integrating devices such as light guiding shades. They are basically shelves with opaque
and translucent areas that are placed on the outside of a window with different inclinations
to cover and redirect the solar lighting to the interior of the room. The researchers also men-
tion the use of angle-selective glazing for radiant heat control [26]. It is worth mentioning
that these resources can be useful in subtropical zones (ranging from 23◦ to 35◦ degrees of
latitude, north or south), since they take advantage of the sun’s inclination with respect to
the zenith, but at latitudes close to the equator, the sun is very vertical all year round, so
these devices are not very useful.

Nguanso et al. discuss the trends in the construction industry in Thailand. The
built-in approach to energy efficiency design does not reflect the current market practice.
Their research examines which components work best together to save energy and reduce
environmental impact in buildings in the tropical region. They propose a reduction in
internal temperatures due to the solar gain by insulating the walls, ceilings and floors. The
openings associated with windows will only be double glazed [32].

The approach of Al-Obadai et al. to reducing the heat in houses in southeast Asia
has focused on avoiding the passage of solar radiation through the roof, to which they
attribute 70% of the heating of a room [33]. This research group explores the passive
cooling techniques, such as reflective roof strategy (to slow down the heat transfer into
a building) and radiative roof (to remove unwanted heat from a building). Both consist
of choosing materials with physical properties that diminish as much as possible the
thermal absorptance [33]. Correspondingly, Akbari et al. showed that replacing the
conventional surface colors with light colors significantly reduces the infrared radiation
and heat absorption [34].

According to Qahtan et al., the success of glazing in the tropics lies in the concept by
it transmits the visible light and reflects outwards the short-wave infrared radiation [35].
They point out that spectrally selective glazing might be an appropriate choice for the
tropics but is not popular due to its high production cost. As an option, they design a solar
control by a sustainable glazed water system, it cools a room by flowing a thin water film
over the outer surface of the windows of the building during the day. They achieve two
important aims to lower the temperatures with this system: the flow of the water film takes
away the heat and lowers the surface temperature, and the water can absorb some solar
energy, limiting the passage of thermal energy. They showed p interesting results, showing



Polymers 2022, 14, 4250 5 of 18

that water reduces the solar heat (infrared) transmittance and maximizes daylight (visible
light) transmittance [35].

2.3. Using Smart Materials

Mahdavinejad et al. affirmed that the term smart window has been applied “to any
system that purports to have an interactive or switchable surface and has functions like
control of optical transmittance, thermal transmittance and absorption and view through the
window” [23]. Therefore, by this point, solutions have been proposed that take advantage
of material properties, but they cannot be classified as smart devices. In this reference, the
group classify the advantages and disadvantages of different kinds of smart windows in a
tropical region, e.g., photochromic, thermochromic, thermotropic, electrochromic, liquid
crystal device and suspended particle device windows [23]. Regarding thermochromic
glazing, the authors claimed that because it responds to heat by partially changing from
transparent to opaque the improvement in thermal comfort comes at the expense of the
view through the window [23].

Hoffmann and Waaijenberg mentioned that color change could be desirable for tropical
greenhouses where there is no problems of plants freezing or suffering from lack of light.
On the contrary, the cooling, shading and diffusing effects are key to decreasing the
temperature, avoiding direct burning of plants and improving the uniformity of the light
intensity inside a greenhouse. Thus, in their research, thermochromic coatings made of
liquid crystal acted as shading materials, without exploring the use of vanadium oxides to
regulate the temperature [36].

In an investigation carried out in India by Singh et al., the authors studied a large-area
smart window fabricated with commercially available thermochromic pigments and gels in
combination with invisible mesh electrodes. Their goal was to design a reasonably priced
smart window with tunable light and temperature to control the glare and infrared radiation
entrance [37]. The device was experimentally tested and showed a reversible change from
completely opaque to transparent, near room temperature. It could be activated by the user
(using electricity) or by heat from the sun [37]. The glazing developed by this group has an
acceptable transparent state below the transition temperature, but when it is reached, the
glazing turns totally opaque to visible light; therefore, the people inside the building lose
the possibility to see through the window and be illuminated by natural light.

Thermochromic pigments were explored by Hu and Yu. In their case, an adaptive
building roof was designed by integrating thermochromic coating and phase change mate-
rial (PCM) layer, which intelligently control both the solar energy absorption/reflection and
thermal energy transfer in the building [37]. The thermochromic coating and PCM used
are commercially available. Through simulation, they showed energy savings compared
to a traditional roof [37]. In the same way as in the investigation of Singh et al., the ther-
mochromic pigment used turns from a transparent state below the transition temperature
to a completely opaque state above it [38]. Thus, their proposal would not be desirable for
a window.

A tunable emissivity multilayer thermochromic smart window was designed by
Wang et al. [39]. They built a system with a thin film indium tin oxide overcoating deposited
on the glass. They added an inner and outer polyethylene layer, and a hydroxypropyl
cellulose hydrogel was added to the system. Their results showed that the system provided
cooling power to the buildings in the hot season and the developed smart window has a
switchable front side and solar emissivity for cold climates too. The last consideration is
unnecessary in tropical zones.

Zhou et al. pointed out that “smart window research usually assumes that the sunlight
radiates in one direction throughout the year while most regions receive solar radiation at
various angles” in different seasons and places [40]. This group constructed a vanadium-
dioxide-based thermochromic smart window, considering the solar elevation angle. Three-
dimensional printing technology was employed to fabricate the tilted microstructures
for modulating solar transmission dynamically. They claimed that the tilt, thickness,



Polymers 2022, 14, 4250 6 of 18

spacing, width and tungsten doping percentage in VO2 can be customized according to
the average temperature and solar elevation angle variation of the sun in a determined
latitude. Through energy consumption simulations in different cities near the Tropic of
Cancer, they showed good results for this device, which they proposed may open a new
era of real-world-scenario smart window exploration.

According to Shen et al., triggering the metal to isolator transition (MIT) by Joule heat-
ing upon voltages applied on VO2-based devices avoids the degradation of thermochromic
performance and the significant reduction in MIT temperature to room temperature [41].
Using this system, they achieved a synergetic result of tungsten doping and hysteresis
behavior of MIT in VO2. The optimal infrared blocking performance could be retained at a
reduced cost of energy consumption and at an ambient temperature down to 47 ◦C, which
coincides with the glass window temperature in the summer in subtropical and tropical
regions. The authors concluded that an optimal infrared blocking performance of VO2
films needed low and even zero energy consumption [41].

Al-Obadai et al. and Hoffmann and Waaijenberg established that, in practice, a restric-
tion on using thermochromic devices is their high cost [33,36]. This is one of the challenges
to be overcome in the design of window coatings.

From the architectural point of view, Heidari et al. mentioned that it is not real
that applying a single device will be the solution for the control of energy in developing
countries. Energy efficiency may be achieved using a combination of several systems and
long-term strategies [42].

3. VO2 in Thermochromic Films
3.1. Advantages of Dispersed VO2 Nanoparticles over a Continuous Thin Film

In the following section, important figures of merit of thermochromic coatings are in-
troduced. We briefly discuss the advantage of using vanadium dioxide (VO2) nanoparticles
embedded in a dielectric matrix (e.g., a polymeric matrix) instead of continuous VO2 thin
films for improving the performance of thermochromic smart windows. A more detailed
description can be found elsewhere [43,44].

Here, the two relevant aspects to consider are the amount of solar and luminous
radiation that can be transmitted by the device, which could be described by the integral
luminous Tlum and solar Tsol transmittances, respectively. Tlum and Tsol are given by

Tlum,sol =

∫
ϕlum,sol(λ)T(λ) dλ∫

ϕlum,sol(λ) dλ
, (1)

where ϕlum(λ) is the relative luminous efficiency of the eye [45] (see Figure 3a), and ϕsol(λ)
is the solar irradiance at sea level, which is typically depicted by the AM 1.5 standard spec-
trum [46] (see Figure 3a). In general, a transparent glazing is desired, which corresponds
to a high Tlum value. Regarding Tsol, the important quantity in thermochromic coatings
is the contrast ∆Tsol between the integral luminous transmittance in the semiconducting
Tsol(τ < τC) and metallic Tsol(τ > τC) state, which is defined as follows [44].

∆Tsol = Tsol(τ < τC)− Tsol(τ > τC), (2)

where τ is the temperature at the glazing, and τC is the critical temperature. The higher
the value of ∆Tsol, the more significant energy-saving effect can be achieved by the ther-
mochromic smart window.



Polymers 2022, 14, 4250 7 of 18

Polymers 2022, 14, x FOR PEER REVIEW  7 of 19 
 

 

thin films for improving the performance of thermochromic smart windows. A more de‐

tailed description can be found elsewhere [43,44]. 

Here, the two relevant aspects to consider are the amount of solar and luminous ra‐

diation that can be transmitted by the device, which could be described by the integral 

luminous 𝑇  and solar 𝑇  transmittances, respectively. 𝑇  and 𝑇  are given by 

𝑇 ,
𝜑 , 𝜆 𝑇 𝜆  d𝜆
𝜑 , 𝜆  d𝜆

,  (1)

where 𝜑 𝜆  is  the  relative  luminous  efficiency  of  the  eye  [45]  (see  Figure  3a),  and 

𝜑 𝜆  is the solar irradiance at sea level, which is typically depicted by the AM 1.5 stand‐

ard spectrum [46] (see Figure 3a). In general, a transparent glazing is desired, which cor‐

responds to a high 𝑇  value. Regarding 𝑇 , the important quantity in thermochromic 

coatings is the contrast ∆𝑇  between the integral luminous transmittance in the semicon‐

ducting 𝑇 𝜏 𝜏  and metallic 𝑇 𝜏 𝜏  state, which is defined as follows [44]. 

∆𝑇 𝑇 𝜏 𝜏 𝑇 𝜏 𝜏 ,  (2)

where 𝜏 is the temperature at the glazing, and 𝜏  is the critical temperature. The higher 

the value of ∆𝑇 , the more significant energy‐saving effect can be achieved by the ther‐

mochromic smart window. 

 

Figure 3. (a) Spectra portraying the relative luminous efficiency of the eye [45] and the solar irradi‐

ance at sea level for a clear weather with the sun standing 37° above the horizon, corresponding to 

the AM 1.5 standard spectrum [46]. Spectral transmittance (b) and reflectance (c) of a VO2 thin film 

(50 nm thick) in its semiconducting and metallic state [47]. Calculation for the spectral transmittance 

(d) and reflectance (e) of a 5 μm thick dielectric matrix with a dispersion of VO2 nanospheres with 

an effective thickness of 50 nm for the semiconducting and metallic state [48]. Panels (b)–(e) were 

adapted from Ref. [44], Copyright 2016, with permission from Elsevier. 

Figure 3b,c depict the typical spectral transmittance and reflectance of a continuous 

50 nm thick VO2 thin film in the semiconducting and metallic state [47]. On the other hand, 

Figure 3d,e show the calculations of the same quantities in the case of VO2 nanospheres 

dispersed in a 5 μm thick dielectric matrix with a volume factor of 0.01 and an effective 

thickness of 50 nm [48]. 

The reflectance in the nanoparticle case does not show a significant variation between 

the metallic and semiconducting state (see Figure 3e), in contrast with what is observed 

for the thin film (see Figure 3c). Thus, the transmittance changes in Figure 3d can be as‐

cribed mainly to absorption. 

As depicted in Figure 3a, the relative luminous efficiency of the eye is only relevant 

within a spectral region between about 400 and 700 nm. One of the main drawbacks of the 

continuous thin film case is the low 𝑇  due to the low transmittance (of about 40 to 50%) 

Figure 3. (a) Spectra portraying the relative luminous efficiency of the eye [45] and the solar irradiance
at sea level for a clear weather with the sun standing 37◦ above the horizon, corresponding to the
AM 1.5 standard spectrum [46]. Spectral transmittance (b) and reflectance (c) of a VO2 thin film
(50 nm thick) in its semiconducting and metallic state [47]. Calculation for the spectral transmittance
(d) and reflectance (e) of a 5 µm thick dielectric matrix with a dispersion of VO2 nanospheres with
an effective thickness of 50 nm for the semiconducting and metallic state [48]. Panels (b)–(e) were
adapted from Ref. [44], Copyright 2016, with permission from Elsevier.

Figure 3b,c depict the typical spectral transmittance and reflectance of a continuous
50 nm thick VO2 thin film in the semiconducting and metallic state [47]. On the other hand,
Figure 3d,e show the calculations of the same quantities in the case of VO2 nanospheres
dispersed in a 5 µm thick dielectric matrix with a volume factor of 0.01 and an effective
thickness of 50 nm [48].

The reflectance in the nanoparticle case does not show a significant variation between
the metallic and semiconducting state (see Figure 3e), in contrast with what is observed for
the thin film (see Figure 3c). Thus, the transmittance changes in Figure 3d can be ascribed
mainly to absorption.

As depicted in Figure 3a, the relative luminous efficiency of the eye is only relevant
within a spectral region between about 400 and 700 nm. One of the main drawbacks of the
continuous thin film case is the low Tlum due to the low transmittance (of about 40 to 50%)
between about 400 and 700 nm. By comparison, at the same spectral region, the dispersed
nanospheres case presents higher transmittance (see Figure 3d), which yields a higher Tlum
value with respect to that of the continuous thin film.

For the continuous thin film, the difference in transmittance between the semicon-
ducting and metallic state is more pronounced at around 2500 nm (see Figure 3b), which
corresponds to a spectral region with low solar irradiance (see Figure 3a). Regarding the
nanospheres case, an interesting aspect to notice in Figure 3d is the minimum of transmit-
tance in the metallic state between about 1000 and 1500 nm. An important consequence of
this feature, which can be assigned to the plasmonic absorption effects [49], is an increase
in ∆Tsol with respect to that of the continuous thin film. This is because for the nanospheres
case, the region of higher difference between the transmittances of the semiconducting and
metallic states shifts toward lower wavelengths in comparison to the continuous thin film
case, which is a spectral region with higher solar irradiance than that at about 2500 nm
(see Figure 3a).

In summary, for practical applications, it is preferable to use a thermochromic glazing
based on a dielectric matrix with dispersed VO2 nanoparticles rather than the continuous
thin film version. For comparable configurations in particular, the former gives higher Tlum
and ∆Tsol values than the latter.



Polymers 2022, 14, 4250 8 of 18

3.2. Hydrothermal Synthesis of Monoclinic VO2 for Thermochromic Applications

Hydrothermal synthesis consists of generating a chemical reaction in an aqueous
medium, and it is a method of producing metal oxide particles. It was developed in the
early 1970s by researchers such as Matijevic, who used an autoclave at room temperature
and atmospheric pressure to synthesize chromium hydroxides [50]. From his work, it
seems that the first step of the reaction is the hydrolysis of the metal salt solution to produce
hydrated oxide particles, and the second part is its dehydration to produce the metal oxide.
However, the hydrated metal oxides are also produced, and the reaction rate is low because
the temperature is usually not high enough for dehydration. It is advisable to carry out
hydrothermal processes at the highest possible temperature and pressure [51].

The synthesis of nanoparticles for thermochromic oxides has been reported using
the hydrothermal method through different routes [52,53], one of its advantages is that
it allows doping the material in the same production of vanadium oxide [54]. On the
other hand, due to the multiple oxidation states of vanadium and its many polymorphic
forms, it could be quite a challenge to prepare one single phase of vanadium oxide [55].
Variables such as temperature, time, pressure, precursor addition rate, reducing agents and
others should be carefully controlled [53,56,57] (see Table 1). Even though the product of
hydrothermal synthesis is usually a mixture of two or more of these forms, it is possible to
bring them to VO2(M) by means of an annealing process [58]. This implies a second step to
achieve the synthesis of the thermochromic material [4]. One-step hydrothermal synthesis
of monoclinic VO2(M) powders has become a research focus to avoid the aggregation and
growth of nanoparticles during a second step heat treatment [18].

Table 1. Common hydrothermal conditions, crystallography data and comments on VO2 polymorphs
(from Ref. [59] with permission from John Wiley and Sons).

Common
Reaction

Conditions
Polymorphs

Unit cell
Parameters

a, b, c
(10−10 m)

β (◦) Space
Group Comments Ref.

V source:
V2O5, VOSO4,
NH4VO3

VO2 (B)
12.054,
3.693,
6.424

106.96 C2/m

It has a reversible structural switch
between the crystalline and
amorphous phase under
high pressure.

[60]

Reductant: H2C2O4,
N2H4

VO2 (A)
8.450,
8.450,
7.678

90 P42/ncm

It has an intermediate phase
between VO2(B) and
VO2(R), and a reversible phase
transition at ≈ 162 ◦C.

[15,19]

Surfactant: PVP *,
PEG ** VO2 (M)

5.752,
4.538,
5.383

122.64 P21/c

The most widely studied
inorganic thermochromic
material, and most applications are
based on the MIT.

[19]

pH regulator: HCl,
HNO3, H2SO4,
CO(NH2)2

VO2 (R)
4.554,
4.554,
2.856

90 P42/mnm

It has a high temperature phase of
VO2(M) and a reversible phase
transition with VO2(M) at
τc ≈ 68 ◦C.

[61]

Doping element: W,
Mo, Mg VO2 (D)

4.597,
5.684,
4.913

89.39 P2/c

A new phase was first reported by
Xie et al., and
it can be transformed into VO2(M)
at temperature as low as 300 ◦C.

[62]

Temperature:
≈180–260 ◦C
Time: From a few
hours to a few days

VO2 (P)
4.890,
9.390,
2.930

90 Pbnm

It was synthesized using a simple
chemical reaction route by Wu et al.,
and it can be transformed into
VO2(M) by fast annealing.

[63]

* PVP: polyvinylpyrrolidone, ** polyethylene glycol.



Polymers 2022, 14, 4250 9 of 18

As can be seen in Table 1, the literature shows that vanadium oxides can be synthe-
sized by hydrothermal methods using several processes, such as reduction in pentavalent
vanadium compounds (V2O5 or NH4VO3) with different reducing agents, as well as
homogeneous precipitation of VOSO4 under mild hydrothermal conditions [53]. The hy-
drothermal method usually requires temperatures around 240 ◦C [18] and reaction times
of a few hours up to two days [18,19,59,64] to obtain VO2(M) in a one-step hydrothermal
reaction process [18]. The control of pH and inert atmosphere are key factors to achieving
the synthesis of VO2(M), since the acid conditions and oxygen lead to non-thermochromic
forms of vanadium oxides. Some investigations report pH values from neutral to slightly
basic [64], indicating that the gradual and uniform rise in pH can result in the nucleation
and growth of uniformly nanosized particles [19].

A one-step direct synthesis of pure monoclinic VO2 nanoparticles by continuous
hydrothermal flow synthesis has been reported, which is a variation of the hydrothermal
method described above. It used a jet of supercritical water mixed with dissolved metal
salts of the precursor at room temperature. It allows the reproduction and scalability of the
system for manufacturing purposes [65].

3.3. Methods Used to Include VO2 NPs in Polymeric Films

VO2 nanoparticles can be used as thermochromic materials because of the changes in
optical properties as a reaction to the temperature. This results in windows that selectively
modulate the light that passes through them. However, constructing a window that
includes VO2 nanoparticles (NPs) as part of it is a challenge to be studied.

In this section, we classify and discuss the different methods used to include VO2
NPs in polymeric matrices to finally form a composite material that could work as a ther-
mochromic window. Table 2 summarizes the relevant references classifying the methods of
obtaining the VO2 nanoparticles, the type of polymer, film thickness and nanoparticles size.

Table 2. Relevant references for combinations of polymers and VO2 nanoparticles.

Synthesis
Method Polymer Used Notes Film Thickness (nm) NP Size (nm) Year Ref.

Polyethylene terephthalate
(PET) 2013 [66]

Polyvinylphenol 1 mm 950 2014 [9]

hydrothermal and
pyrolysis 22 2015 [67]

hydrothermal Polydimethylsiloxane
(PDMS) (matrix)

Films were dried and
cured 10–200 2016 [68]

hydrothermal Polyvinyl butyral (PVB)
(matrix)

The film was deposited
by spin coating and later
dried up.

40 2017 [69]

sol–gel Polyvinylpyrrolidone
(PVP) (film promoter)

PVP was decomposed
during annealing. 100 17–20 2017 [70]

hydrothermal Poly(methyl methacrylate)
(PMMA) (matrix)

Electrospinning and hot
pressing used for layer
formation.

30 2017 [71]

thermal treatment
of bead mill

Polyvinylpyrrolidone
(PVP) (matrix) and
Polyethylene terephthalate
(PET) as substrate

30–60 2018 [72]

hydrothermal Polyethylene (PE)
(coating)/EVA (matrix)

PE is used to stabilize
VO2. 300,000 17.4 2019 [73]

Poly(methyl methacrylate)
(PMMA)

Wood template used as
a base. 2019 [74]

hydrothermal Polyaniline (PANI)
The use of PANI
maintains VO2
thermochromicity.

- 2019 [75]



Polymers 2022, 14, 4250 10 of 18

Table 2. Cont.

Synthesis
Method Polymer Used Notes Film Thickness (nm) NP Size (nm) Year Ref.

Polyvinyl alcohol and
Polydimethylsiloxane
(PVA/ PDMS) (matrix)

Polymer chosen due to
high transparency on
the Vis and IR regions.

60 2020 [76]

hydrothermal Poly(methyl methacrylate)
(PMMA) (matrix)

The film was deposited
using blade coating
method.

4000 50–80 2020 [77]

hydrothermal
dMEMUABr
copolymerized with
PMMA

1400 (length)
149 (width) 2020 [78]

annealing Polyethylene terephthalate
(PET) (substrate)

Direct transfer was used
for film deposition. 75,000 3.7 2021 [79]

Polyacrilonitrile (PAN)
(matrix) Electrospinning. 2021 [80]

hydrothermal Poly(N-isopropyl
acrylamide) 20–50 2021 [81]

Since 2013, efforts have been made to produce VO2 glazing on a surface of 2.72 m2 [66].
A PET film was covered with VO2 and finally adhered to a glass substrate, creating a
composite material with a phase transition temperature of 41.3 ◦C. However, there is limited
information on the film fabrication methodology [9]. In this reference, polyvinylphenol
was also used as a polymeric matrix together with commercial VO2 particles that were
treated with an ultrasonic device to decrease its size and perform IR modulation.

VO2 NPs—with a size between 10 and 200 nm—have been combined with elastomeric
polymers, such as polydimethylsiloxane (PDMS), to explore the influence of film thickness
on solar energy modulation [68], as the film could be stretched and released to control the
width of the path that solar irradiance must go through. Another polymer widely used on
thermochromic windows is polyvinyl butyral (PVB), as it is commercially available and
normally utilized for these kinds of applications [82]. The same polymer, PVB, functions as
a matrix in which the VO2 particles are placed; the NPs are dispersed using an ultrasound
device, and the suspension is stirred to be deposited later onto a glass substrate via spin
coating, followed by a thermal treatment [69].

Polyvinylpyrrolidone (PVP) has been employed to form a matrix in which VO2
nanoparticles were embedded [72]. Once the NPs were synthesized, they were mixed
with PVP and some solvents to form a castable slurry, which was later applied to a flexible
substrate (PET) through a roll-to-roll method. Then, after applying heat, the solvents
evaporated and formed a solid film with well-dispersed VO2 nanoparticles. Moreover,
PVP has been used as a film promoter during a sol–gel synthesis process with annealing, in
which an ambient rich in NH3 was used to prevent the further oxidation of VO2 [70].

VO2 nanoparticles must be stabilized because of their tendency to oxidize relatively
fast [73]. According to this reference, one possibility of avoiding the VO2 → V2O5 chemical
reaction is to cover the particles with polyethylene (PE) shell, which results in changes not
only to the structure but also to the optical properties. Additionally, the covered VO2 NPs
are combined with ethylene vinyl acetate (EVA), which functions as a matrix, forming films
of about 0.3 mm.

PMMA has also been mixed with VO2 NPs, being used as a polymeric matrix via
electrospinning and hot pressing to develop nanocomposite films [71]. These films can be
stacked to improve mechanical behavior. Another approach was followed in Ref. [77]. After
being synthesized with a hydrothermal method, the VO2 NPs were dispersed in PMMA us-
ing an ultrasound with the objective of providing high lifetimes for the VO2 NPs. According
to the authors, the PMMA final structure was highly crosslinked after being irradiated with
UV radiation (220–380 nm). The PMMA/VO2 film was deposited on a Polyethylene tereph-
thalate (PET) layer via the blade-coating method. With the idea of creating a thermochromic
window with an antimicrobial functionality, PMMA has been co-polymerized via UV curing
with N,N-dimethyl-N-{2-[(2-methylprop-2-enoyl)oxy]ethyl}undecane-1-aminium bromide



Polymers 2022, 14, 4250 11 of 18

(dMEMUABr), where the VO2 NPs were dispersed. Using an adhesive–coated PET, the
previously synthesized VO2 NPs on a mica substrate were removed and placed on the
flexible PET layer, forming the PET/VO2/mica material [79]. The solar modulation of this
system reached 36.1% at 25 ◦C, and 90.3% of the bacteria analyzed were killed.

With the objective of developing a smart energy-efficient window that included privacy
as another functionality, research inspired by cephalopod skin has been developed [76].
A polydimethylsiloxane (PDMS) elastomeric matrix with dispersed VO2 nanoparticles was
prepared. Additionally, a polyvinyl alcohol (PVA) layer was added on top by drop casting.
Here, it is important to point out that the PDMS composite material is stretched up to 175%
to recreate the structure of the film to provide privacy. Moreover, PVA and PDMS were
chosen due to their relatively high transparency on the UV–NIR spectrum.

To achieve an infrared stealth material, antimony tin oxide was combined with VO2
and polyacrylonitrile, as described in Ref. [80]. Using an electrospinning and sintering
process, the composite nanofibrous material was able to decrease its IR emissivity around
68 ◦C, corresponding to the phase change from a monocyclic unit cell to a rutile phase of
the VO2 [81].

Even though several formulations have been reviewed, VO2 particle concentration
and the effect of the polymer matrix and formulation on the thermochromic performance
must be addressed to optimize the window properties for tropical weather.

3.4. Why Is Necessary to Reduce the Particle Size?

VO2 particle size control is critical for window applications where transparency is a
requirement. To achieve an ideal control regarding the modulation of infrared radiation
with minimal effect on visible light transmittance, the literature indicates that the particles
must be less than 100 nm in size [16]. However, it was reported that even sizes of about
50 nm may be reached [65]. It has been reported that the size of the VO2 NPs can be
controlled by using different annealing temperatures, making it possible to change the
optical properties of the deposited films, as well as enabling large-scale synthesis [83].

The size of the particles resulting from the synthesis is on a scale of microns, so it can
be detected by the human eye and also produces visible light scattering, which results in a
decrease in visual transparency through the glass [18,84].

From the optics point of view, there are difficulties in maintaining the high trans-
mittance of transparent polymeric matrices when the particles of inorganic materials are
dispersed in them due to the difference in the refractive index of the particles and the
polymeric matrix. Another factor on which transparency strongly depends is the radius of
the scattered particles. It is possible to minimize the scattering losses in systems containing
fine particles of one to two orders of magnitude smaller than the wavelength of light [85].

In reducing the particle size, a balance must be reached, since reducing it to very
small sizes enhances the formation of agglomerates, which deteriorates dispersion in the
polymeric matrix [85].

Computational modeling indicates that the loss of light intensity due to particle
scattering in the polymeric matrix can become negligible if the particle size is reduced
below 100 nm [16], which is consistent with the information shown in Table 2.

VO2 Particle Size Reduction Methodologies

In general, when choosing a technique for particle size reduction in solid materials,
the principal aim is achieving a narrow particle distribution, maintaining repeatability
along the process. Mechanical methods seem to fulfill this requirement. As an example,
in the pharmaceutical industry, those techniques are used to improve the solubility of
drugs. This strategy results in increased surface area, increased saturation solubility and
decreased diffusional distance, all of which lead to an increase in the extent and the rate of
dissolution [86]. Additionally, for the mining industry, particle size reduction is necessary
to obtain a final product with fewer pollution agents. The ideal target particle size for



Polymers 2022, 14, 4250 12 of 18

comminution is the liberation size, the size about which the valuable mineral can be
effectively separated from the gangue by physical or chemical methods [87].

Wet jet milling was developed as a novel mixing and dispersion method for a suspen-
sion, in which the agglomerates are pulverized by turbulent and shear flows generated
from the high-speed injection into an exclusive canal [88,89]. It has been reported as a tool
for accomplishing a significant particle size reduction in solids [89].

A wet jet variation is called jet milling. In this micronization method, high-velocity
compressed air streams are injected into a chamber where the originally raw materials are
fed with a rate-controlled feeder. As the particles enter the air stream, they are accelerated
and caused to collide with each other and the wall of the milling chamber with high
velocities [90]. The pressure regulation in the chamber allows to introduce the energy into
the system. As a general rule, the higher the pressure, the higher the particle velocity,
which leads to a broad particle size distribution by the end of the process. In Ref. [91],
different tests with tungsten powder, with an average size of 1µm, 3 µm, 5 µm, 10 µm, were
performed. The results showed that particle size reduction was achieved for most of the
sample, and above all, the particle size distribution became narrower, which is the goal
when performing the jet milling technique.

Another approach for particle size reduction is the combination of two or more meth-
ods because each of them has its own advantages. For example, in Ref. [92], an aluminum–
iron blend was used to create nanoparticles with jet milling and ball milling techniques.
The greatest reduction reached approximately 50 nm, in contrast to irregularly shaped and
sized particles in the micron range achieved using ball milling alone.

As mentioned before, ball milling helps in particle size reduction. In this device,
a suitable powder charge (typically, a blend of elemental) is placed in a high-energy mill,
along with a suitable milling medium [93]. The goal of milling is to reduce the particle
size and blending of particles in new phases. The balls may roll down the surface of
the chamber in a series of parallel layers, or they may fall freely and impact the powder
and balls beneath them [94]. It was shown that these strategies can be applied to a wide
group of materials. In Ref. [95], quartz (SiO2) from two different locations was treated in
a ball-milling process at durations of 4 min, 120 min, 960 min and 1920 min. Afterward,
the SEM and laser scattering results showed an effective particle size reduction in each
period. For example, 100 µm average particle size was achieved at 4 min versus 10 µm at
the longest time [95].

Despite all the techniques described above, ball milling seems a suitable technique to be
applied in the fabrication of thermochromic windows, and also, it has a good projection for
industrial-scale use. The advantages of this technique include cost effectiveness, reliability,
ease of operation, reproducible results due to energy and speed control, applicability in wet
and dry conditions on a wide range of materials (e.g., cellulose, chemicals, fibers, polymers,
hydroxy-apatite, metal oxides, pigments, catalysts) [96].

4. Conceptual Device

The characteristics of a vanadium dioxide VO2-based thermochromic smart window
designed for tropical areas should focus on the specific need for thermal comfort by
modulating the internal temperature of the enclosures, which, in a tropical area, during
the day, tend to reach temperatures well above 25 ◦C. Temperature regulation must be
achieved by avoiding affecting the transmittance of the visible light spectrum, since, in
the tropics, the daylight lasts approximately 12 hours throughout the year, which makes
it possible to avoid dependence on artificial lighting. According to Wang et al., there is
research to be conducted on these two fronts, mainly studying the dopants that both reduce
VO2 transition temperature and improve the optical properties of the coatings [97]. In this
way, we could design devices that really contribute to the energy efficiency of a room.

In the case of nanoparticles embedded in a polymer matrix, there are some advantages
regarding the flexibility [98], and the tailor design of the optical properties of the final
composite film [20]. On the one hand, it is possible to adjust the particle size, the level



Polymers 2022, 14, 4250 13 of 18

of doping, and therefore, the transition temperature [64]. The VO2 particle concentration
and the addition of liquid crystals may enhance other color hues [99]. The use of a VO2
particle size distribution or same-sized particles within the polymer matrix with different
doping levels may allow adjusting the dynamics of the window to tune its modulation at
different temperatures.

Figure 4 shows the scheme of three possible window designs that can be reached.
In addition to the requirements indicated in the previous paragraph, needs such as the
protection of coating to avoid VO2 degradation and protecting the user must be considered
because of the toxicity of vanadium compounds. Figure 4a presents a multilayer device in
which the window glass is the substrate to which the VO2-active material coating would be
adhered and sealed with a protective coating that could have anti-reflection, self-cleaning
properties, if necessary, depending on the requirements of the customer [97]. It can be
tailored to have some specific coloration and even selective dispersion characteristics,
taking advantage of the properties of liquid crystals [100].

Polymers 2022, 14, x FOR PEER REVIEW  14 of 19 
 

 

tailored to have some specific coloration and even selective dispersion characteristics, tak‐

ing advantage of the properties of liquid crystals [100]. 

   
(a)  (b) 

 
(c) 

Figure 4. Diagrams of possible useful devices for the design of intelligent thermochromic windows. 

Manufacture (a) monolithic, (b) multilayer, (c) roll out system. 

An alternative approach of laminating two glass panels with the active material in 

between  is shown  in Figure 4b. In this configuration, the optics of the window may be 

affected due to the thick glass. However, this presents various advantages, as  it can be 

improved with self‐cleaning and antireflection coatings, but more importantly, it gives the 

possibility of using colored glass with different hues, which opens vast prospects for ar‐

chitecture  facade design and art  installations  [101] without neglecting  the comfort and 

energy saving. 

Figure 4c offers one further step on scaling up the window manufacture. In this case, 

the protective coating layer would be made of flexible glass or plastic mesh, which would 

act as a substrate for the active material, so the coating process could easily become a roll 

out process, which could even be extended to the application of the self‐cleaning of anti‐

reflective coatings. There are two possibilities for the substrate cover material: a PET plas‐

tic web or a flex glass. PET plastic is more affordable but may have the inconvenience of 

its optical transparency being inferior to the flex glass. Potentially, the roll out design al‐

lows easy cover of flat or non‐flat windows, so it can be used to retrofit windows already 

built, which makes this system very versatile in terms of usage and costs and with a min‐

imum weight footprint [67]. 

There are  investigations of methods  to prevent  the degradation over  time of VO2 

compounds, as  they gradually  transform  into V2O5, which  is  thermodynamically more 

stable but not thermochromic. W2O3 coatings have been shown to be a barrier to vanadium 

oxidation at temperatures and humidity consistent with those of the tropics [2], and could 

be included in the configurations proposed in Figure 4a,c. 

It is important to consider that in the economic reality of tropical areas, the proposed 

solutions must be adaptable to different budgets in order to be accessible to as many peo‐

ple as possible.  

Figure 4. Diagrams of possible useful devices for the design of intelligent thermochromic windows.
Manufacture (a) monolithic, (b) multilayer, (c) roll out system.

An alternative approach of laminating two glass panels with the active material in
between is shown in Figure 4b. In this configuration, the optics of the window may be
affected due to the thick glass. However, this presents various advantages, as it can be
improved with self-cleaning and antireflection coatings, but more importantly, it gives
the possibility of using colored glass with different hues, which opens vast prospects for
architecture facade design and art installations [101] without neglecting the comfort and
energy saving.

Figure 4c offers one further step on scaling up the window manufacture. In this case,
the protective coating layer would be made of flexible glass or plastic mesh, which would
act as a substrate for the active material, so the coating process could easily become a
roll out process, which could even be extended to the application of the self-cleaning of
antireflective coatings. There are two possibilities for the substrate cover material: a PET
plastic web or a flex glass. PET plastic is more affordable but may have the inconvenience of



Polymers 2022, 14, 4250 14 of 18

its optical transparency being inferior to the flex glass. Potentially, the roll out design allows
easy cover of flat or non-flat windows, so it can be used to retrofit windows already built,
which makes this system very versatile in terms of usage and costs and with a minimum
weight footprint [67].

There are investigations of methods to prevent the degradation over time of VO2
compounds, as they gradually transform into V2O5, which is thermodynamically more
stable but not thermochromic. W2O3 coatings have been shown to be a barrier to vanadium
oxidation at temperatures and humidity consistent with those of the tropics [2], and could
be included in the configurations proposed in Figure 4a,c.

It is important to consider that in the economic reality of tropical areas, the proposed
solutions must be adaptable to different budgets in order to be accessible to as many people
as possible.

Currently, the field of smart thermochromic windows based on vanadium is intensively
studied but still has many possibilities for new contributions. The objective of this review is
to summarize the strategies that, integrated with new ideas in the construction of buildings,
provide options for quality of life and energy savings for the inhabitants of the tropics.

5. Conclusions

In this review, we bring together the most relevant research related to thermochromic
smart windows to shed light on the challenges and opportunities in developing these
devices for countries with a tropical weather. The importance of using vanadium dioxide
(VO2) thermochromic nanoparticles dispersed in a polymeric matrix is highlighted as
an alternative to increase its stability in practical applications, as well as contributing to
improve smart window energy-saving features. The methods reported in the literature for
the synthesis of VO2, the polymer matrices normally utilized and the deposition procedures
are thoroughly described. Additionally, the configuration and the material functionalities
proposed for an ideal conceptual device suited to the weather conditions found in the
tropics are discussed. Despite all the challenges in the design of thermochromic VO2-
polymer-based smart windows exposed in this review, there are weighty possibilities for
VO2-polymer films regarding their potential use for thermal and light comfort in tropical
areas, where the sun shines practically vertically and for many hours throughout the
year. As a result, this article contributes to the quest for a device that could help bring
thermochromic windows in a practical application in the near future for the tropics.

Author Contributions: Conceptualization, N.M.-Q., R.S.-P. and E.A.-S.; Investigation, N.M.-Q., V.V.-G.,
E.A.R.-G. and A.C.-C.; Writing—Original Draft, N.M.-Q., V.V.-G., E.A.R.-G. and A.C.-C.; Writing—
Review and Editing, N.M.-Q., V.V.-G., R.S.-P. and E.A.-S.; Visualization, N.M.-Q., Supervision, E.A.-S.
All authors have read and agreed to the published version of the manuscript.

Funding: This research was funded by Vicerrectoria de Investigación del Instituto Tecnológico de
Costa Rica (ITCR) through Project 5401-1450-1701 and Vicerrectoria de Investigación de la Universi-
dad de Costa Rica through Project C0032, (“VENTANAS INTELIGENTES: APLICACIONES A LA
EFICIENCIA ENERGÉTICA EN EL DISEÑO ARQUITECTÓNICO DE FACHADAS”).

Institutional Review Board Statement: Not applicable.

Data Availability Statement: Not applicable.

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Research on Glazing in the Tropics 
	Geographical and Climatic Situation 
	Cooling Spaces Using Material Properties 
	Using Smart Materials 

	VO2 in Thermochromic Films 
	Advantages of Dispersed VO2 Nanoparticles over a Continuous Thin Film 
	Hydrothermal Synthesis of Monoclinic VO2 for Thermochromic Applications 
	Methods Used to Include VO2 NPs in Polymeric Films 
	Why Is Necessary to Reduce the Particle Size? 

	Conceptual Device 
	Conclusions 
	References