It may soon be possible to charge mobile phones, change the tint on windows, or power small toys with peel-and-stick versions of solar cells, thanks to a partnership between Stanford University and the US Department of Energy’s National Renewable Energy Laboratory (NREL).
Peel-and-stick, or water-assisted transfer printing (WTP), technologies were developed by the Stanford group and have already been used in nanowire-based electronics.
The Stanford-NREL partnership has now conducted the first successful demonstration using actual thin-film solar cells, according to NREL principal scientist Qi Wang.
The university and NREL have shown that thin-film solar cells less than one-micron thick can be removed from a silicon substrate used for fabrication by dipping them in water at room temperature. Then, after exposure to heat of about 90°C for a few seconds, they can attach to almost any surface.
Wang met Stanford counterpart Xiaolin Zheng at a conference last year where Wang gave a talk about solar cells and Zheng talked about her peel-and-stick technology.
It was at that event that Zheng realised that NREL had the type of solar cells needed for her peel-and-stick project.
NREL’s cells could be made easily on Stanford’s peel-off substrate. NREL’s amorphous silicon cells were fabricated on nickel-coated Si/SiO2 wafers.
A thermal release tape attached to the top of the solar cell serves as a temporary transfer holder. An optional transparent protection layer is spin-casted in between the thermal tape and the solar cell to prevent contamination when the device is dipped in water.
The result is a thin strip much like a bumper sticker: the user can peel off the handler and apply the solar cell directly to a surface.
“It’s been a quite successful collaboration,” Wang said. “We were able to peel it off nicely and test the cell both before and after. We found almost no degradation in performance due to the peel-off.”
Zheng said cells can be mounted to almost any surface because almost no fabrication is required on the final carrier substrates.
The cells’ ability to adhere to a universal substrate is unusual; most thin-film cells must be affixed to a special substrate.
The peel-and-stick approach allows the use of flexible polymer substrates and high processing temperatures.
The resulting flexible, lightweight, and transparent devices then can be integrated on to curved surfaces such as military helmets and portable electronics, transistors and sensors.
In the future, the collaborators will test peel-and-stick cells that are processed at even higher temperatures and offer more power.
Zheng said the partnership between Stanford and NREL has been key for this successful work.
“NREL has years of experience with thin-film solar cells that allowed us to build upon their success,” she said. “Qi Wang and (NREL engineer) William Nemeth are very valuable and efficient collaborators.”
A scientific paper, “Peel and Stick: Fabricating Thin Film Solar Cells on Universal Substrates”, appears in the online version of Scientific Reports, a subsidiary of the world-famous UK scientific journal Nature.