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CZTSSe solar cell shows realistic potential for commercialization

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Marie Freebody, Contributing editor, [email protected]

Scientists at Purdue University in West Lafayette, Ind., have developed a thin-film solar cell from Earth-abundant materials. They say that their CZTSSe solar cell, which is made from CZTS nanocrystals, could provide a cost-friendly alternative to current thin-film solar cells on the market.

As supplies of common rare-earth elements dwindle, the solar cell community is forced to explore more plentiful sources from which to fabricate cells. Qijie Guo and colleagues in the university’s Solar Energy Research Group turned to copper, zinc, tin and sulfur for a viable solution.

Purdue University scientists have fabricated a CZTSSe thin-film solar cell, which exhibits the large, densely packed grains desired for high-efficiency devices. ITO = indium tin oxide. Courtesy of the Journal of the American Chemical Society.

“Current leading thin-film technologies require rare-earth elements, such as indium for Cu(In,Ga)(S,Se)(CIGSSe), or tellurium for CdTe,” Guo said. “In the long run, to meet the worldwide demand for electricity, we need elements that will not have any limitation on their availability. Also, the relative abundance of these elements [copper, zinc, tin and sulfur] should result in lower cost for input materials to make solar cells.”

When it comes to solar cells, efficiency is one key measure of success. Some of the major thin-film solar cells currently available in the marketplace, including CdTe, CIGSSe and amorphous silicon, have module efficiencies of between 8 and 12 percent. While the new CZTSSe solar cell has a total area efficiency of just 7.2 percent, Guo points out that this is a very promising start.

“All the materials in the marketplace have been in development for over three decades. It has taken years of research and better understanding of the device performance that has led to their current improved performance,” he said. “Our CZTSSe efficiency compares well with the efficiencies of the solar cells from these materials (CdTe, CIGSSe, etc.) in their early days of development.”

And it is the method adopted by the Purdue group that really sets it apart from other efforts in the field. Early in 2010, researchers at IBM fabricated a similar solar cell that offered a remarkable 9.6 percent total area efficiency. However, rather than using a vacuum-based process or the hazardous chemical hydrazine, Guo explains that their solution phase approach is not only safer but also less expensive.

“The efficiency of our CZTS-based solar cell is better than the alternate technologies such as physical vapor deposition methods, and it is second only to the IBM method, which uses toxic and unsafe hydrazine,” he said. “Therefore, we have been successful in demonstrating the potential of solar cells from this class of materials via an attractive and safe route.”

At left is a scanning electron microscope image of a cross section of the CZTSSe solar cell, which demonstrates a total area efficiency of 7.2 percent (right). Courtesy of R. Agrawal, Purdue University.

In the approach, nanocrystal inks are used in place of hydrazine-based reactants to deposit the low-cost elements onto a glass substrate. Details of the method are published in a paper by Qijie Guo, Grayson M. Ford, Wei-Chang Yang, Bryce C. Walker, Eric A. Stach, Hugh W. Hillhouse and Rakesh Agrawal, appearing in the Nov. 19, 2010, online edition of the Journal of the American Chemical Society.

Commenting on the economic viability of the CZTSSe solar cell, Guo said: “As solar cells become even more of a commodity product, any edge in materials or production cost becomes significant. By reducing materials cost and supply constraints using Earth-abundant elements, CZTSSe is expected to have a competitive advantage over thin-film materials such as CIGSSe and CdTe.”

The group has its sights set firmly on commercialization and hopes to further improve efficiencies to more than 10 percent.

“Although it is difficult to speculate [about] the timing of such advancement, we hope to achieve this goal in the near future,” Guo said. “After that, the challenge will be to scale the technology from the lab to commercial production level. Once we have achieved the desired lab-scale efficiency, the large-scale production will probably take two to three years.”

Photonics Spectra
Feb 2011
Metal used in components of the crystalline semiconductor alloys indium gallium arsenide (InGaAs), indium gallium arsenide phosphide (InGaAsP), and the binary semiconductor indium phosphide (InP). The first two are lattice-matched to InP as the light-emitting medium for lasers or light-emitting diodes in the 1.06- to 1.7-µm range, and the last are used as a substrate and cladding layer.
The material favored for study of interaction of high-acoustic intensities with free carriers. Tellurium is the semiconductor with the largest piezoelectric constants. Tellurium oxide is the material of choice for the storage medium in optical mass data storage systems.
(InAmerican Chemical SocietyCdTeCIGSSecopperCZTS nanocrystalsCZTSSeEarth-abundant elementsenergyGa)(SGreenLightGuohydrazineIBMindiumMarie FreebodyMicroscopynanonanocrystal inksopticsPurdue UniversityQijie Guorare-Earth elementsSe)2Solar Energy Research Groupsulphurtelluriumthin film solar celltinzinc

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