GTRI researcher Stephan Turano shows an optical microscope image of one of the carbon nanotube array patterns on a solar cell that will be tested on the International Space Station. The actual cell is visible on microscope stage under the objective. (Credit: Gary Meek, Georgia Tech)

A novel three-dimensional solar cell design developed at Georgia Tech will soon get its first testing in space aboard the International Space Station. An experimental module containing 18 test cells was launched to the ISS in July and will be installed on the exterior of the station to study the cells’ performance and their ability to withstand the rigors of space.

In addition to testing the three-dimensional format, the module will also study a low-cost copper-zinc-tin-sulfide (CZTS) solar cell formulation. In all, the module launched to the ISS contains four types of PV devices: 3-D cells based on conventional cadmium telluride, 3-D cells based on CZTS materials, traditional planar solar cells produced at Georgia Tech, and planar cells based on CZTS.

“We want to see both the light-trapping performance of our 3-D solar cells and how they are going to respond to the harshness of space,” said Jud Ready, a principal research engineer at the Georgia Tech Research Institute (GTRI) and an adjunct professor in the Georgia Tech School of Materials Science and Engineering. “We will also measure performance against temperature, because temperature has an influence on the performance of a solar cell.”

Built by coating miniature carbon nanotube “towers” with a photo-absorber that captures sunlight from all angles, the 3-D cells developed by Ready’s lab could boost the amount of power obtained from the small surface areas many spacecraft have. The cells would absorb light from any direction, eliminating the need for mechanical devices to aim PV modules toward the sun. The PV cell experiment will be installed on the NanoRacks External Platform (NREP), where robustness of the solar cells will be studied under harsh space conditions for six months.

"The CZTS photovoltaic arrays were built using the readily available elements copper, zinc, tin and sulfur to replace rarer CIGS – copper, indium, gallium and selenium – which are used in similar thin-film solar cells," said Ready. "The CZTS approach produces an efficient photo-absorber using earth-abundant materials that cost around a thousand times less than rare-earth elements like indium, gallium and selenium."

One virtue of CZTS photovoltaic material is its electron band structure. Like CIGS, CZTS is a direct band gap material. In semiconductor physics, this means incoming solar photons are able to emit current-producing electrons directly, rather than moving through power-robbing intermediate states as indirect band gap materials, like silicon, require. Moreover, Ready said, direct band gap materials have good resistance to the powerful ionizing radiation encountered in space. That's because direct band gaps are larger than indirect band gaps; it's harder for radiation to damage these larger gaps so severely that functionality is seriously impaired.

The 3-D capability could prove especially valuable on the International Space Station, which is exposed daily to 15-16 sunrises and sunsets as it orbits Earth every 92 minutes at 17,150 m.p.h. The 3-D towers can exploit the sun's rays for longer periods than conventional 2-D planar – or flat – designs, which work most efficiently only when the sun is directly overhead. As the ISS orbits, the 3-D arrays' performance will be compared to a high quality commercial 2-D planar cell array installed nearby. If things go as expected, GTRI's cells will provide relatively better performance than the other cells as they move away from high noon. The new CZTS 3-D arrays will also be tested in space against an older 3-D design made by GTRI using cadmium telluride.

GTRI's photovoltaic arrays will be encased in Lexan containers aboard the ISS. Lexan, a clear yet strong polymer, produces minimal interference with incoming solar rays but can protect the delicate arrays from astronauts and space debris – and also protect the crew from any pieces of the arrays that might separate. After the six-month mission, the solar cells will be sent back to Earth via a cargo ship. The research team will assess the cells’ post-mission performance and look for damage from radiation and other space hazards.

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