The phononic metafabric used to produce the novel Janus thermal cloak. Photo: Huaxu Qiao.
The phononic metafabric used to produce the novel Janus thermal cloak. Photo: Huaxu Qiao.

When an electric vehicle is parked outside, its temperature can swing wildly from day to night and season to season, which can lead to deterioration of the battery. To dampen these fluctuations and extend the battery’s lifespan, researchers have designed an all-season thermal cloak that can cool an electric vehicle by 8°C on a hot day and warm it by 6.8°C at night.

The cloak, made predominantly of silica and aluminum, can do this passively without outside energy input and operates without any modification between hot or cold weather.  The researchers describe the cloak in a paper in Device.

“The thermal cloak is like clothes for vehicles, buildings, spacecrafts or even extraterrestrial habitats to keep cool in summer and warm in winter,” says senior author Kehang Cui, a materials scientist at Shanghai Jiao Tong University in China.

To dampen natural temperature fluctuations, the cloak isolates the car – or any other object beneath it – from the surrounding environment. The cloak has two components: an outer layer that efficiently reflects sunlight and an inner layer that traps heat inside. Whatever heat the outer layer does absorb is emitted in such a way that it can be readily dissipated to outer space. This design inspired the researchers to name it the Janus thermal cloak, after the two-faced Roman god Janus.

“The cloak works basically the same way the Earth cools down, through radiative cooling,” says Cui. “The earth is covered by the atmosphere, and the atmosphere is transparent to a certain range of electromagnetic energy we radiate.” 

While this process is desirable in the summer, it would make the car colder during winter months. “You have to develop something that can turn on and off by itself without external energy input, and that's extremely difficult,” says Cui.

Cui and his team designed the cloak to automatically counteract this cooling in the winter. To do this, the cloak employs an effect called ‘photon recycling’ – essentially, any energy that is trapped under the cloak will bounce back and forth between the car and cloak rather than escape to the surroundings outside. 

To assess the performance of the thermal cloak, the researchers conducted tests on electric vehicles parked outside under typical ambient conditions in Shanghai. While the cabin temperature of an uncovered car reached 50.5°C at mid-day, the cabin of the cloak-covered car was 22.8–27.7°C lower than the uncovered car and 7.8°C lower than the temperature outside. At midnight, the covered car stayed 6.8°C higher than the temperature outside, never dropping below 0°C.

“This is the first time that we could achieve warming above the ambient temperature by almost 7°C during winter nights,” says Cui. “This is also kind of surprising to us – there’s no energy input or sunshine and we can still get warming.”

The outer component of the cloak is made of thin fibers of silica coated in flakes of hexagonal boron nitride, a ceramic material similar to graphite that enhances the fibers’ solar reflectivity. These fibers are then braided and woven together into a fabric and adhered to the inner layer, which is made of aluminum alloy.

The team purposefully designed the cloak to make production easier to scale-up in the future. For example, using thinner silica fibers would have increased solar reflectivity, but they would be weaker and couldn’t be made using high-volume, industrial-level production techniques. In addition, the materials used, including the aluminum, silica and boron nitride, are all low-cost and make the cloak lightweight, durable and fire-retardant.

This story is adapted from material from Cell Press, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.