To Generate More Solar Power, Put This Material on Glass

Transparent solar materials on windows could gather as much energy as bulkier rooftop solar units, say researchers.

The authors of a new paper argue that widespread use of such highly transparent solar applications, together with the rooftop units, could nearly meet US electricity demand and drastically reduce the use of fossil fuels.

“Highly transparent solar cells represent the wave of the future for new solar applications,” says Richard Lunt, an associate professor of chemical engineering and materials science at Michigan State University. “We analyzed their potential and show that by harvesting only invisible light, these devices can provide a similar electricity-generation potential as rooftop solar while providing additional functionality to enhance the efficiency of buildings, automobiles, and mobile electronics.”

Lunt and colleagues pioneered the development of a transparent luminescent solar concentrator that, when placed on a window, creates solar energy without disrupting the view. The thin, plastic-like material can be used on buildings, car windows, cell phones, or other devices with a clear surface.

The solar-harvesting system uses organic molecules developed by Lunt and his team to absorb invisible wavelengths of sunlight. The researchers can “tune” these materials to pick up just the ultraviolet and the near-infrared wavelengths that then convert this energy into electricity.

Moving global energy consumption away from fossil fuels will require such innovative and cost-effective renewable energy technologies. Only about 1.5 percent of electricity demand in the United States and globally is produced by solar power.

In terms of overall electricity potential, however, the authors note that there is an estimated 5 billion to 7 billion square meters of glass surface in the United States. With that much glass to cover, transparent solar technologies have the potential of supplying some 40 percent of energy demand in the US—about the same potential as rooftop solar units.

“The complimentary deployment of both technologies,” Lunt says, “could get us close to 100 percent of our demand if we also improve energy storage.”

Lunt says highly transparent solar applications are recording efficiencies above 5 percent, while traditional solar panels typically are about 15 percent to 18 percent efficient. Although transparent solar technologies will never be more efficient at converting solar energy to electricity than their opaque counterparts, they can get close and offer the potential to cover a lot more additional surface area, he says.

Right now, transparent solar technologies are only at about a third of their realistic overall potential, Lunt adds.

“That is what we are working towards,” he says. “Traditional solar applications have been actively researched for over five decades, yet we have only been working on these highly transparent solar cells for about five years. Ultimately, this technology offers a promising route to inexpensive, widespread solar adoption on small and large surfaces that were previously inaccessible.”

The researchers published their work in the journal Nature Energy.

The National Science Foundation and the US Department of Education funded the study.

Lunt’s coauthors are from Michigan State and Ubiquitous Energy Inc., a company Lunt cofounded with Barr to commercialize transparent solar technologies.


This article appeared of Futurity. Read the original article.

Source: Michigan State University

Original Study DOI: 10.1038/s41560-017-0016-9

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