Electrochromic smart window for modulation of infrared heat
The majority of global energy generation in our modernised society originates from the burning of fossil fuel which is unsustainable in a long time horizon. Energy consumption in the category of electricity for air-conditioning and indoor lighting in commercial and residential buildings account f...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2021
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| Online Access: | https://hdl.handle.net/10356/147818 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The majority of global energy generation in our modernised society originates from the burning
of fossil fuel which is unsustainable in a long time horizon. Energy consumption in the category
of electricity for air-conditioning and indoor lighting in commercial and residential buildings
account for about one third of total consumption. It was found that more than half of the heat
that enters a building through its windows come from the solar radiation in the near infrared
(NIR) region. As a result, in an attempt to lower energy consumption of houses and buildings,
smart window technology has been introduced. For a smart window to be function, the material
has to exhibit qualities such as dual-band modulation in the NIR and visible range, which
permits selective modulation of NIR heat sans influencing visible light transmission. An ideal
electrochromic material for the application of smart windows should have high NIR
modulation, high visible light transmission, fast switching between bleached and coloured
states and excellent long term stability.
To meet the functional needs, we proposed a novel Nd-Mo co-doped SnO2/α-WO3
electrochromic material in this project. Compared to conventional SnO2/α-WO3 ECs, our Nd-
Mo co-doped SnO2/α-WO3 ECs displays up to 62% NIR modulation (at wavelength 1200nm),
90% visible light transparency (at λ = 600nm), high colouration efficiency (~200 cm2.C−1), fast
switching time with minimal electrochromic performance drop of 31% (compared to 59% of
undoped sample) following a stability test of 1000 cycles. The improved electrochromic
performance is due the existence of Nd-Mo co-dopants that restrict the trapping of Li+ ions
within the α-WO3 framework. This reduces the degree of crystallization of α-WO3 layer and
improves the electronic conductivity by transferring excess electrons to the conduction band of
the SnO2. The current composition of ECs showcased in this report is one of the better
electrochromic material to be utilised in the application of smart windows to the best of the
author’s knowledge. |
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