Physics Charge Smartphones Clothes Made From Carbon Nanotubes

Physicists from the University of Cincinnati will soon be able to charge smartphones using clothes made from carbon nanotubes. With the assistance of their colleagues from the BBC, Wright-Patterson, the experts intend to create a special material, which because of the peculiarities of carbon nanotubes would be exceptionally heat-resistant conducting electricity, and will also differ for their durability. Professor mark Schultz, is also involved in the study declared that the task of scientists is to use the resistance and conductivity for energy storage, which can charge a variety of gadgets.

Schulz said that at the moment the science is on the verge of a “carbon revolution,” as this material may soon completely replace metals because of its strength, low weight and various additional properties. Yarns made from nanotubes can store energy, replacing bulky batteries, which soon altogether sink into oblivion.

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New Knitting Technique Produces Electronic Smart Fabrics at Industrial Scales

New Knitting Technique Produces Electronic Smart Fabrics at Industrial Scales

Meet the bike shorts of the future.

Image: BluIz60/

Australian scientists have developed a knitting technique capable of producing electrically-conductive Spandex-carbon nanotube hybrid textiles at industrial scales. As described earlier this month in a paper published in ACS Nano, the stretchable fabrics “exhibit excellent performance” as sensors and artificial muscles. Potential applications include adjustable smart clothing, robotics, and medical devices.

At the core of the material is regular old Spandex, which is basically artificial super-rubber spun into fibers. In the process outlined in the paper, SPX filaments are coated with aerogel sheets of carbon nanotubes. Carbon nanotubes have the neat property of tunable electrical conductivity, and by tweaking the fabrication process, it’s possible to create materials with electrical and mechanical properties that change as the fabric changes shape. Meet the bike shorts of the future.

“The coating method operates at room temperature, requires no solvents, and does not compromise textile production speeds,” the Australian team reports. As such, the hybrid yarns are also pretty cheap to produce—a key requirement.

What makes the stuff really interesting is how it converts electricity into mechanical work. With an applied voltage, it’s possible to get the textile to contract by as much as 33 percent as it heats up. The material then relaxes as the voltage is removed and it cools down. This mechanical power output maxes out at around 1.28 kW/kg, which, the paper notes, is well beyond what’s offered by mammalian skeletal muscle. To demonstrate, the researchers used their new material to implement a knee brace, as below:

Another possible biomedical application is as a “lymph sleeve,” a compression sleeve used to treat lymphedema, a common side effect of cancer treatments.

“The lymph sleeve, for example, will be developed using lightweight actuating fabric that will detect swelling and then respond by ‘squeezing’ the arm to enhance lymph flow,” Javad Foroughi, the lead author of the new paper, told Physics World.  “We are also investigating the possibility of employing it in artificial-heart muscles for positive support of the right ventricle.”

Original story by Michael Byrne / Motherboard

Carbon Nanotubes Could Provide the Military With Battery-Power in Textiles

Carbon Nanotubes Could Provide the Military With Battery-Power in Textiles

The carbon fibers can be spooled into strong, conductive thread. Like spider silk, it is stretchy and strong. Credit: Joseph Fuqua II/UC Creative Services
Carbon nanotubes could lead to clothing that can double as a battery, a discovery that could be particularly useful for the military.

A team from the University of Cincinnati—in a partnership with the Wright-Patterson Air force base—are working to take advantage of the properties of carbon nanotubes in developing new applications for soldiers in the field.

“The major challenge is translating these beautiful properties to take advantage of their strength, conductivity and heat resistance,” UC professor Vesselin Shanov, who co-directs UC’s Nanoworld Laboratories, said in a statement.

Graduate student Mark Haase has worked with Air Force researchers over the past year to find applications for carbon nanotubes using X-ray computer tomography to analyze samples.

“This pushes us to work in groups and to specialize,” Haase said in a statement. “These are the same dynamics we see in corporate research and industry. Engineering is a group activity these days so we can take advantage of that.”

The researchers used chemical vapor deposition to grow the carbon nanotubes on silicon wafers the size of a quarter under heat in a vacuum chamber.

“Each particle has a nucleation point,” Haase said. “Colloquially, we can call it a seed. Our carbon-containing gas is introduced into the reactor. When the carbon gas interacts with our ‘seed,’ it breaks down and re-forms on the surface. We let it grow until it reaches the size we want.”

UC’s Nanoworld Lab set a world record in 2007 by growing a nanotube that stretched nearly two centimeters, the longest carbon nanotube array produced in a lab at the time. The lab can currently create nanotubes that are substantially longer.

They were able to stretch the little fibrous square over an industrial spool in the lab to convert the sheet of carbon to a spun thread that can be woven into textiles.

“It’s exactly like a textile,” Shanov said. “We can assemble them like a machine thread and use them in applications ranging from sensors to track heavy metals in water or energy storage devices, including super capacitors and batteries.”

This ultimately could lead to a much lighter load for soldiers in battle.

“As much as one-third of the weight they carry is just batteries to power all of their equipment,” Haase said. “So even if we can shave a little off that, it’s a big advantage for them in the field.”

The study was published in Materials Research Express.
Full article by Kenny Walter – Digital Reporter @RandMagazine here.

eTextile Wristband Controls Small Household Appliances

Video: Watch a simple fabric wristband control small household appliances

[Image above] Credit: American Chemical Society, YouTube

We have come quite a long way from the TV remote control.

Technology has undoubtedly made our lives a lot easier in many respects. We’ve just about reached the point where we will be able to control nearly everything in our home remotely with the touch of a smartphone.

But for those little tasks inside the home, why bother with a smartphone? What if you wanted to use small appliances or your computer without messing with the on/off switches on each device?

Several researchers have already solved that problem by designing electronic textiles that could enable users to control a computer or small appliance by swiping a finger over fabric.

Although e-textiles are already on the market in many forms, the researchers wanted to improve upon existing technology. Most have “poor air permeability, can’t be laundered or are too costly or complex to mass-produce,” according to a news story from the American Chemical Society.

So the researchers developed a self-powered nanogenerator by screen-printing conductive carbon nanotube ink onto nylon fabric. And since this was a wearable device, of course, it needed to be washable. They combined polyurethane, a synthetic polymer, with the carbon nanotubes, adhering them to the fabric. After wrapping the entire device with silk and turning it into a wristband, the researchers connected the device to a computer and other small appliances to demonstrate how it could turn on and control appliances from several feet away.

And according to the researchers in the article, their e-textile is inexpensive to mass produce.

Besides making life easier for us able-bodied folks, the device could also help those with limited mobility or even disabled people better navigate their environment.

The paper, published in ACS Nano, is “Screen-Printed Washable Electronic Textiles as Self-Powered Touch/Gesture Tribo-Sensors for Intelligent Human–Machine Interaction” (DOI: 10.1021/acsnano.8b02477).

Original Article Published on June 20th, 2018 | By: Faye Oney

Watch the video below to see how the e-textile device can control small household appliances and a computer.