Tag Archives: Brigham Young University

Nanotechnology-enabled football helmets could help to determine if players have a concussion

Here’s a video from Brigham Young University (BYU, located in Utah, US) describing their researchers’ football helmet innovation (Note: Within the first 30 seconds the speaker makes what sounds like an error, nanoparticles can range from 1/60,000 to 1/100,000 of the size of a hair not 1/100 as he seems to state),

A Nov. 6, 2013 news item on Nanowerk describes why researchers felt it was important to create ‘smart’ foam that can detect the severity of an impact,

Concussions in college and professional football are under the microscope more than ever these days, but they don’t seem to be slowing down in frequency.

Nearly every game produces an incident where a player suffers “concussion-like symptoms.” According to the CDC [US Centers for Disease Control and Prevention], more than 1.6 million sports-related concussions happen annually, with football being the sport with the highest concussion risk.

The Nov. 5, 2013 Brigham Young University (BYU) news release, which originated the news item, provides more details about the motivations for this research (Note: A link has been removed),

While the NFL [US National Football League] and NCAA [National Collegiate Athletic Association] are trying to address the mounting concerns, BYU student Jake Merrell is developing technology that may change the concussion game.

Combining nanotechnology with foam, Merrell has created a smart-foam that can be placed inside a football helmet to measure the impact of each hit. When compressed, the self-powered foam generates electrical signals that are transmitted wirelessly to a tablet or computer in the hands of a coach or trainer.

“A coach will know within seconds exactly how hard their player just got hit,” Merrell said. “Even if a player pops up and acts fine, the folks on the sidelines will have data showing that maybe he isn’t OK.”

Merrell’s working prototype recently won a top three finish (and $2,000) at BYU’s Student Innovator of the Year competition. To read more about the other SIOY winners . …

While companies such as Riddell and Schutt are trying to make helmets that reduce the risk of concussion, a study from the University of Wisconsin shows that no brand is actually succeeding.

The NFL and helmet makers have recently thrown more resources at investigating concussions, but current technology only provides data through bulky accelerometers in the crown of a helmet. Merrell’s piezoelectric foam accounts for both force and acceleration to measure actual impact.

Working under the tutelage of BYU mechanical engineering professor David Fullwood, Merrell was researching silicone-based motion sensors when he decided to combine a conductive mixture to foam to see what happened. To his surprise, the foam created a voltage.

“Jake is the one who pushed testing the sensors in silicon foam and he is the one who discovered that it is piezoelectric – that it creates voltage when compressed,” Fullwood said. “Jake is very proactive, talking to people in the industry and pushing hard to make it work.”

As part of his efforts, Merrell plans to submit a proposal to the upcoming Head Health Challenge sponsored by GE [General Electric], the NFL and Under Armour. The challenge was created to find new ways to measure football impact in real time to improve player safety.

Already, Merrell’s research on the nano-foam has landed him National Science Foundation funding, and a top paper award at an American Society of Mechanical Engineers conference.

Beyond football, Merrell hopes his piezoelectric self-sensing foam is able to transform any foam into an impact sensor for a wide range of applications, from law enforcement to the automotive industry.

It would have been nice to have had more technical details about the ‘smart’ foam for which I can see applications such as bicycle helmets, construction hard hats, baby seats, soldiers’ helmets, and more. I wish the researchers good luck with the idea.

Love Day’s nano carbon tube cupid from Brigham Young University (Utah, US)

Valentine’s Day which is sometimes also known as ‘Love Day’, is being celebrated at Brigham Young University with an image of cupid made from carbon nanotubes according to the university’s Feb. 12, 2013 news release,

Got a “little crush” on someone this Valentine’s Day? Maybe you’ve been hit by a little arrow belonging to this cupid made from carbon nanotubes by Brigham Young University physics students.

You don’t have to be a science lover to be amazed at how they build on such a small scale. First, they put a pattern of microscopic iron “seeds” onto a plate. A blast of heated gas causes a miniature forest of carbon nanotubes to spring up. Each nanotube measures about 20 atoms across and is 99 percent air.

And while love is in the air, both love and the nano-cupid are fragile.

“It’s a really fragile structure at this point – blowing on it or touching it would destroy it,” said BYU physics professor Robert Davis.

To strengthen both the cupid and other micro-machines, Davis and his colleague Richard Vanfleet coat the nanostructures with metals and other materials. That opens the door to all kinds of uses.

I’m not sure how the carbon nanotube (CNT) cupid can be described as a machine, micro or otherwise, since the CNTs seem merely to be arranged in a pattern that is cupid-shaped,

This cupid's arm is the width of a human hair. It's made from nanotubes that are 10,000 times smaller. Courtesy Brigham Young University

This cupid’s arm is the width of a human hair. It’s made from nanotubes that are 10,000 times smaller. Courtesy Brigham Young University

In any event, it seems this news release is more concerned with other research being performed,

For example, the researchers can design and produce filters with higher precision than other methods. Their process makes equally-sized holes that are about one-tenth the circumference of a human hair. And unlike other micro-filters, the holes are evenly spaced throughout the filter.

“One application is in the area of compressed gases like oxygen in the areas of health care, mining operations or scuba diving,” Davis said. “Compressed gas systems can generate particles that need to be filtered out.”

Lawrence Barrett, a junior studying physics, recently took the concept to a business plan competition and was crowned Utah’s “Innovation Idol.” His winning presentation almost didn’t get off the ground. Barrett first learned about the competition just 48 hours before the entry deadline.

“I worked on the proposal through the night and Dr. Davis edited it for me on a Saturday,” Barrett said.

There’s a lot of information and ideas packed into this news release to the point where it’s overcrowded. Still, it does seem that exciting things are happening in Utah.