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Fraunhofer ISE Develops the World's Most Efficient Solar Cell with 47.6 Percent Efficiency

Mithilfe einer neuen Antireflexbeschichtung ist es gelungen, die Effizienz der bisher besten Vierfachsolarzelle von 46,1 auf 47,6 Prozent zu erhöhen. © Fraunhofer ISE / Thanks to improved antireflection layers, the efficiency of the best four-junction solar cell to date improved from 46.1 to 47.6 percent.  © Fraunhofer ISE
Mithilfe einer neuen Antireflexbeschichtung ist es gelungen, die Effizienz der bisher besten Vierfachsolarzelle von 46,1 auf 47,6 Prozent zu erhöhen. © Fraunhofer ISE / Thanks to improved antireflection layers, the efficiency of the best four-junction solar cell to date improved from 46.1 to 47.6 percent. © Fraunhofer ISE
Mithilfe einer neuen Antireflexbeschichtung ist es gelungen, die Effizienz der bisher besten Vierfachsolarzelle von 46,1 auf 47,6 Prozent zu erhöhen. © Fraunhofer ISE / Thanks to improved antireflection layers, the efficiency of the best four-junction solar cell to date improved from 46.1 to 47.6 percent.  © Fraunhofer ISE
Mithilfe einer neuen Antireflexbeschichtung ist es gelungen, die Effizienz der bisher besten Vierfachsolarzelle von 46,1 auf 47,6 Prozent zu erhöhen. © Fraunhofer ISE / Thanks to improved antireflection layers, the efficiency of the best four-junction solar cell to date improved from 46.1 to 47.6 percent. © Fraunhofer ISE
Der Wirkungsgrad der neuen Vierfachsolarzelle steigt bis zu einer Konzentration des Sonnen-lichts von 665 an und erreicht hier erstmals einen Wert von 47,6 Prozent. © Fraunhofer ISE
Der Wirkungsgrad der neuen Vierfachsolarzelle steigt bis zu einer Konzentration des Sonnen-lichts von 665 an und erreicht hier erstmals einen Wert von 47,6 Prozent. © Fraunhofer ISE
The efficiency of the new four-junction solar cell increases with concentration up to 665 suns, reaching a value of 47.6 percent conversion efficiency for the first time. © Fraunhofer ISE
The efficiency of the new four-junction solar cell increases with concentration up to 665 suns, reaching a value of 47.6 percent conversion efficiency for the first time. © Fraunhofer ISE
Quanteneffizienz der neuen Vierfachsolarzelle: Die oberste Teilzelle aus GaInP absorbiert das kurzwellige Sonnenlicht im sichtbaren Spektralbereich. Infrarotes Licht wird in den darunter liegenden Teilzellen aus AlGaAs, GaInAsP und GaInAs umgewandelt. © Fraunhofer ISE
Quanteneffizienz der neuen Vierfachsolarzelle: Die oberste Teilzelle aus GaInP absorbiert das kurzwellige Sonnenlicht im sichtbaren Spektralbereich. Infrarotes Licht wird in den darunter liegenden Teilzellen aus AlGaAs, GaInAsP und GaInAs umgewandelt. © Fraunhofer ISE
Quantum efficiency of the new four-junction solar cell. The top sub-cell made of GaInP absorbs short-wave sunlight in the visible spectral range. Infrared light is converted in the sub-cells un-derneath which are made of AlGaAs, GaInAsP and GaInAs respectively. © Fraunhofer ISE
Quantum efficiency of the new four-junction solar cell. The top sub-cell made of GaInP absorbs short-wave sunlight in the visible spectral range. Infrared light is converted in the sub-cells un-derneath which are made of AlGaAs, GaInAsP and GaInAs respectively. © Fraunhofer ISE

Researchers at the Fraunhofer Institute for Solar Energy Systems ISE, using a new antireflection coating, have successfully increased the efficiency of the best four-junction solar cell to date from 46.1 to 47.6 percent at a concentration of 665 suns. This is a global milestone, as there is currently no solar cell with a higher efficiency worldwide. The results were presented at the 2nd International tandemPV Workshop in Freiburg, Germany.

For the last two years, Fraunhofer ISE has been working on an ambitious project called "50 Percent." The aim of the project, which is funded by the German Federal Ministry for Economic Affairs and Climate Action BMWK, is to develop a solar cell with 50 percent efficiency for the first time. To achieve this, each individual layer of the complex multi-junction solar cell undergoes further optimization. Improvements in the process technology are incorporated for metal contacts and antireflection layers. Now the project team has achieved a first breakthrough: Their latest solar cell under concentrated sunlight achieves an efficiency of 47.6 percent.

"We are thrilled with this result, which was achieved only one year after the opening of our new Center for High Efficiency Solar Cells," says Dr. Frank Dimroth, department head of III-V Photovoltaics and Concentrator Technology at Fraunhofer ISE. "In our research, we aim to make concentrating photovoltaics even more efficient and competitive, as we believe that this is the most sustainable form of renewable electricity generation."

The layer structure of the new solar cell was developed back in 2016 together with the French company Soitec Inc., that designs and manufactures innovative semiconductor materials. The upper tandem solar cell is made of gallium indium phosphide (GaInP) and aluminum gallium arsenide (AlGaAs), which was bonded by Soitec onto a lower tandem solar cell made of gallium indium arsenide phosphide (GaInAsP) and gallium indium arsenide (GaInAs).

Now an improved contact layer and a 4-layer antireflection coating were applied to the tandem cell structure in Fraunhofer ISE’s Center for High Efficiency Solar Cells. These measures reduce the resistance losses and the reflection on the front side of the cell, which is spectrally sensitive within a broad range of 300 and 1780 nanometers. Conventional solar cells made of silicon absorb sunlight only up to a wavelength of 1200 nanometers and thus do not require such a broadband antireflection coating.

Multi-junction solar cells made of III-V compound semiconductors have always been among the most efficient solar cells in the world. They reach their highest potential when the incoming sunlight is concentrated by lenses onto miniature solar cell devices of just a few square millimeters in size. "Possible applications of such highly efficient tandem solar cells include concentrator photovoltaic systems, which contribute to efficient power generation in sun-rich countries,” says Prof. Dr. Stefan Glunz, division director of Photovoltaics Research at Fraunhofer ISE. "With tandem photovoltaics, it is possible to leave the limitations of single-junction solar cells behind and ultimately achieve a reduction in solar power costs."


Fraunhofer-Institut für Solare Energiesysteme ISE
79110 Freiburg
Germany

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