Researchers at the National University of Singapore (NUS)have developed two new aerogels that can potentially be used for radiative cooling in buildings and the absorption of electromagnetic waves (EMWs) emitted by electronic devices.
Traditionally used to provide thermal insulation in the aerospace industry, aerogels are known for their porosity and low density. These solid materials offer versatile functionality – from gobbling up fat globules in weight-management supplements to facilitating more sustainable metal-recycling processes.
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Utilising plastic waste, the research team engineered thin-film aerogels that function as thermal insulators and radiative coolers. These aerogels can be applied to any surface, such as building roofs, to reduce internal temperatures, offering a scalable and sustainable solution for energy-free thermal management.
The NUS researchers also devised a simple, scalable method to produce aerogels that absorb EMWs in the X-band, characteristic of those used in weather monitoring and air traffic control. These lightweight, durable aerogels protect against electromagnetic pollution, shielding both humans and sensitive equipment.
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The researchers’ work builds on their prior successes in developing aerogels from a variety of waste materials, from plastics and paper to agricultural by-products such as pineapple leaves.
Traditional cooling systems, such as air conditioners, have a ravenous appetite for energy, accounting for about 20 per cent of electricity used in buildings worldwide. The new aerogels developed by the NUS team present a passive cooling alternative, leveraging the natural process of radiative cooling to dissipate heat into space without consuming energy.
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‘This process involves using specially engineered aerogels to emit infrared radiation through the atmospheric “sky window”, effectively cooling surface temperatures below ambient levels,’ said Associate Professor Duong Hai-Minh from the Department of Mechanical Engineering under the NUS College of Design and Engineering. ‘We are excited to be able to upcycle fibres from disposable polyethylene terephthalate (PET) bottles for the new aerogels designed for this purpose to help address the global plastic waste crisis.’
Previously, the team had worked with PET fibres to produce aerogels, but this latest method is significantly more energy-efficient, consuming about 97 per cent less energy and reducing production time by 96 per cent. When tested in Singapore’s warm climate, 0.5 centimetres of the material produced a cooling effect of 2°C, achieved by emitting infrared heat into the surroundings while exhibiting good heat insulation, preventing heat absorption from the surrounding environment.
‘These aerogels could reduce energy consumption in both residential and commercial buildings, especially in tropical climates, where cooling is now a necessity,’ added Duong.
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Future research will focus on adapting these aerogels for diverse climatic conditions and expanding their applications beyond building insulation, such as in industrial processes where the efficient thermal management of liquid circulation pipes is crucial.
Modern electronic devices emit EMWs that can disrupt nearby equipment and pose health risks, including DNA damage and cancer. It’s thus critical to develop materials that can effectively absorb EMWs to shield both humans and infrastructure from these adverse effects. Applications include enhancing the privacy and security of buildings and protecting sensitive medical equipment.
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To address this need, Duong’s team has developed a scalable and eco-friendly procedure to produce novel aerogels that are effective at EMW absorption. The process involves blending three main components – carbon nanotubes, polyvinyl alcohol and carboxymethyl cellulose – followed by freeze-drying.
The aerogel, with a thickness of about three millimetres – roughly the width of 40 strands of human hair – demonstrated an impressive performance of absorbing 99.99 per cent of EMW energy. Across the entire X-band (8.2–12.4 GHz) of the electromagnetic spectrum, used primarily for radar systems, weather monitoring and air traffic control, the aerogel consistently showed its ability to absorb 90 per cent of EMW energy.
‘In addition to offering a wide absorption bandwidth of 1.2–2.2 GHz in the X-band, our aerogel is also about ten times lighter than existing composites used for EMW absorption,’ said Duong. ‘Unlike other composites, our aerogel requires no mixing with heavy polymer fillers before use.’
The researchers have estimated that producing one square metre of the aerogel, with a thickness of one centimetre, costs less than US$74. This cost is substantially lower than the price of other similar commercial materials, which range from US$133 to above US$740.
Looking ahead, the team plans to refine the aerogels’ mechanical properties, such as flexibility, to broaden their applicability across various building and infrastructure projects. The researchers also aim to conduct real-world tests to fully assess the EMW absorption capabilities of the aerogels in practical scenarios.
The research has been published in Solar Energy and Carbon.