A thin layer of gold or silver helps improve the efficiency of perovskite solar cells, but researchers have found a less expensive material that could enable commercialization of the technology without exorbitant cost.
“Our team has identified a potentially disruptive technology that could help reduce the infrastructure investment for use of highly promising perovskite solar cells in solar panels,” NIU Chemistry Professor Tao Xu said.
Xu and Kai Zhu, a senior scientist in the Chemistry and Nanoscience Center at the U.S. Department of Energy’s National Renewable Energy Laboratory (NREL), led a research team that details its findings in a new paper, “Nickel-Doped Graphite and Fusible Alloy Bilayer Back Electrode for Vacuum-Free Perovskite Solar Cells.” The paper appears in the journal ACS Energy Letters.
“A layer of gold in a solar panel or even a layer of silver is probably too expensive,” Zhu said. “It would make the solar panel not affordable for most people.”
Instead of a precious metal, Xu and Zhu used a nickel-doped graphite layer coupled with a bismuth-indium alloy layer. The two layers can be easily integrated into the perovskite device through painting them on, offering a low-cost fabrication method.
NIU Professor Tao Xu
“Our approach replaces costly gold, commonly used to make the back-metal electrode in these solar cells through an expensive high-temperature vacuum-chamber process,” Xu said. “Instead of gold, we use inexpensive materials that can be readily laminated to thin films at atmospheric pressure and mild temperatures. We think this will be an appealing low-cost solution that could help speed commercialization of perovskite solar cells.”
The research team included four of Xu’s NIU Ph.D. students: Mengyuan Li, Jianxin Wang, Owen S. Wostoupal and Xudong Xiao. Other members of the team were from NREL, Northwestern University and Argonne National Laboratory.
Zhu said the perovskite solar cell made with the new materials yielded a laboratory efficiency of 21%. Further research should boost the efficiency higher and closer to that of perovskites made with precious metals, which hold a record efficiency of 26%. Metal is better than carbon at conducting electricity.
Xu and Zhu have previously collaborated on ways to sequester lead should a perovskite solar cell become damaged, as the cells contain a minute amount of the element.
Perovskite solar cells are made by depositing chemicals onto a substrate. Individual layers all serve a purpose, with the perovskite layer serving as the semiconductor. The photons from sunlight trigger electrons to move in one direction, creating a vacancy—or “hole”—that then moves in the opposite direction. The right energy level is needed to spark this movement, in the process creating an electric current. The graphite material and gold both possess the right energy level.
By eliminating a layer of precious metals, the cost to manufacturer perovskites will be significantly cheaper, the researchers calculated. An analysis suggests that for a perovskite-based solar plant with a gigawatt of power output, using the graphite/alloy bilayer will slash costs of the contact electrodes by a factor of between 4 and 1,000 depending on the other types of materials used for back materials.
“That’s the selling point for this approach,” Zhu said.
The research was funded in part by the Department of Energy’s Solar Energy Technologies Office and by the National Science Foundation. The work is also highlighted by Chemical and Engineering News, a weekly news magazine of the American Chemical Society.
