If woven into clothing, a new low-cost, plastic-based textile could cool your body far more efficiently than is possible with the natural or synthetic fabrics in clothes we wear today.
Scientists say the new family of fabrics could become the basis for garments that keep people cool in hot climates without air conditioning.
“If dissipating thermal radiation were our only concern, then it would be best to wear nothing.” “If you can cool the person rather than the building where they work or live, that will save energy,” says Yi Cui, associate professor of materials science and engineering at Stanford University.
Described in the journal Science, the new material works by allowing the body to discharge heat in two ways that would make the wearer feel nearly 4 degrees Fahrenheit cooler than if they wore cotton clothing.
How it Works
It cools by letting perspiration evaporate through the material, something ordinary fabrics already do. But the material provides a second, revolutionary cooling mechanism: allowing heat that the body emits as infrared radiation to pass through the plastic textile.
The researchers began with a sheet of polyethylene and modified it with a series of chemical treatments, resulting in a cooling fabric.
All objects, including our bodies, throw off heat in the form of infrared radiation, an invisible and benign wavelength of light. Blankets warm us by trapping infrared heat emissions close to the body. Thermal radiation escaping from our bodies is what makes us visible in the dark through night-vision goggles.
“Forty to 60 percent of our body heat is dissipated as infrared radiation when we are sitting in an office,” says Shanhui Fan, professor of electrical engineering who specializes in photonics, which is the study of visible and invisible light. “But until now there has been little or no research on designing the thermal radiation characteristics of textiles.”
To develop the textile, researchers blended nanotechnology, photonics, and chemistry to give polyethylene—the clear, clingy plastic we use as kitchen wrap—a number of characteristics desirable in clothing material: It allows thermal radiation, air and water vapor to pass right through, and it is opaque to visible light.
The easiest attribute was allowing infrared radiation to pass through the material, because this is a characteristic of ordinary polyethylene food wrap. Of course, kitchen plastic is impervious to water rendering it useless as clothing. The fact that it’s see-through doesn’t help much either. The researchers tackled these deficiencies one at a time.
First, they found a variant of polyethylene commonly used in battery making that has a specific nanostructure that is opaque to visible light yet is transparent to infrared radiation, which could let body heat escape. This provided a base material that was opaque to visible light for the sake of modesty but thermally transparent for purposes of energy efficiency.
They then modified the industrial polyethylene by treating it with benign chemicals to enable water vapor molecules to evaporate through nanopores in the plastic, allowing the plastic to breathe like a natural fiber, says postdoctoral scholar Po-Chun Hsu.
That led to a single-sheet material that met their three basic criteria for a cooling fabric. To make this thin material more fabric-like, they created a three-ply version: two sheets of treated polyethylene separated by a cotton mesh for strength and thickness.
Cooler than cotton
To test the cooling potential of their three-ply construct versus a cotton fabric of comparable thickness, they placed a small swatch of each material on a surface that was as warm as bare skin and measured how much heat each material trapped.
New fabric opens vents when it gets wet
“Wearing anything traps some heat and makes the skin warmer,” Fan says. “If dissipating thermal radiation were our only concern, then it would be best to wear nothing.”
The comparison showed that the cotton fabric made the skin surface 3.6 F warmer than their cooling textile. The difference means that a person dressed in the new material might feel less inclined to turn on a fan or air conditioner.
The work continues on several fronts, including adding more colors, textures, and cloth-like characteristics to the material. Adapting a material already mass produced for the battery industry could make it easier to create products. “If you want to make a textile, you have to be able to make huge volumes inexpensively,” Cui says.
The research opens up new avenues of inquiry to cool or heat things, passively, without the use of outside energy, by tuning materials to dissipate or trap infrared radiation, Fan says.“In hindsight, some of what we’ve done looks very simple, but it’s because few have really been looking at engineering the radiation characteristics of textiles.”