New Energy Unveils SolarWindow in Demonstration

The event showcased USF-developed, first-of-its-kind see-thru glass prototype to generate electricity.

 

Photo credit: Aimee Blodgett/USF

 

Media Contact: Vickie Chachere, 813-974-6251

 

TAMPA, Fla. (Sept. 16, 2010) – In the hunt for new ways of creating renewable and clean energy, few technologies have generated as much excitement as the tiny, flexible solar cells developed by USF physicist Xiaomei Jiang in recent years.

 

Now the cutting-edge cells are about to make their debut in a way that could transform how solar energy is generated: in see-thru glass windows capable of generating electricity as light – both natural and artificial – passes through the panels.

 

Her invention was unveiled on campus Thursday in a public demonstration of the new SolarWindow™ technology, the first-of-its-kind, small-scale prototype capable of generating electricity.

 

Electricity generated by New Energy’s SolarWindow™ on prototypes of see-thru glass windows was showcased in USF’s Science Center (SCA), in an event hosted by New Energy Technologies.

 

 “The public demonstration of our novel SolarWindow™ technology is a very exciting milestone for all our stakeholders, including the research team, management, and shareholders of New Energy,” said John A. Conklin, President and CEO of New Energy Technologies, Inc., a Maryland-based company.

 

 “We’re eager to demonstrate how far we have come in developing the first-ever technology of its kind with the potential to radically change the way in which we power the estimated 80 million detached homes and 5 million commercial buildings in America, and throughout the world.”

Electrical power is generated on see-thru glass through solar cell coatings which are sprayed onto surfaces. This patent-pending process enables researchers to spray SolarWindow™ coatings onto glass at room temperature, eliminating expensive and often cumbersome high-temperature or high-vacuum production methods commonly used by current solar manufacturers.

Read the December 2009 USF Magazine story on Xiamoei Jiang's research here.