Tandem solar cell world record: New branch in the NREL chart
The CIGS-Pero tandem cell was realised in a typical lab size of 1 square centimeter. © HZB
The Pero CIGS tandem cells are now shown in the NREL chart (red square dots). The world record is currently held by the HZB with 24.16 %. © NREL
A special branch in the famous NREL-chart for solar cell world records refers to a newly developed tandem solar cell by HZB teams. The world-record cell combines the semiconductors perovskite and CIGS to a monolithic "two-terminal" tandem cell. Due to the thin-film technologies used, such tandem cells survive much longer in space and can even be produced on flexible films. The new tandem cell achieves a certified efficiency of 24.16 percent.
Tandem cells combine two different semiconductors that convert different parts of the light spectrum into electrical energy. Metal-halide perovskite compounds mainly use the visible parts of the spectrum, while CIGS semiconductors convert rather the infrared light. CIGS cells, which consist of copper, indium, gallium and selenium, can be deposited as thin-films with a total thickness of only 3 to 4 micrometers; the perovskite layers are even much thinner at 0.5 micrometers. The new tandem solar cell made of CIGS and perovskite thus has a thickness of well below 5 micrometers, which would allow the production of flexible solar modules.
Suitable for applications in space
"This combination is also extremely light weight and stable against irradiation, and could be suitable for applications in satellite technology in space", says Prof. Dr. Steve Albrecht, HZB. These results, obtained in a big collaboration, have been just published in the renowned journal JOULE.
Extremely thin and efficient
"This time, we have connected the bottom cell (CIGS) directly with the top cell (perovskite), so that the tandem cell has only two electrical contacts, so-called terminals", explains Dr. Christian Kaufmann from PVcomB at HZB, who developed the CIGS bottom cell with his team and he adds "Especially the introduction of rubidium has significantly improved the CIGS absorber material".
Improving the contact
Albrecht and his team have deposited in the HySPRINT lab at HZB the perovskite layer directly on the rough CIGS layer. "We used a trick that we had previously developed," explains former postdoc from Albrecht's group Dr. Marko Jošt, who is now a scientist at the University of Ljubjana, Slovenia. They applied so-called SAM molecules to the CIGS layer, which form a self-organised monomolecular layer, improving the contact between perovskite and CIGS.
Certified efficiency: 24.16 percent
The new perovskite CIGS tandem cell achieves an efficiency of 24.16 percent. This value has been officially certified by the CalLab of the Fraunhofer Institute for Solar Energy Systems (ISE).
NREL-Chart
Since such "2 Terminal" tandem cells made of CIGS and perovskite now represent a separate category, the National Renewable Energy Lab NREL, USA, has created a new branch on the famous NREL chart for this purpose. This chart shows the development of efficiencies for almost all solar cell types since 1976. Perovskite compounds have only been included since 2013 - the efficiency of this material class has increased more steeply than any other material.
Prof. Dr. Steve Albrecht heads a BMBF-funded junior research group at HZB and is a junior professor at the Technical University of Berlin. Dr. Christian Kaufmann heads a research group at HZB's PVcomB. Recently, several world records for tandem solar cells made of perovskite in combination with inorganic semiconductors have been reported from HZB.Currently, Albrecht's team also holds the world record for tandem cells made of silicon and perovskite with 29.1 percent, which is also listed in the NREL charts.
- A new way to control the magnetic properties of rare earth elementsThe special properties of rare earth magnetic materials are due to the electrons in the 4f shell. Until now, the magnetic properties of 4f electrons were considered almost impossible to control. Now, a team from HZB, Freie Universität Berlin and other institutions has shown for the first time that laser pulses can influence 4f electrons- and thus change their magnetic properties. The discovery, which was made through experiments at EuXFEL and FLASH, opens up a new way to data storage with rare earth elements.
- BESSY II shows how solid-state batteries degradeSolid-state batteries have several advantages: they can store more energy and are safer than batteries with liquid electrolytes. However, they do not last as long and their capacity decreases with each charge cycle. But it doesn't have to stay that way: Researchers are already on the trail of the causes. In the journal ACS Energy Letters, a team from HZB and Justus-Liebig-Universität, Giessen, presents a new method for precisely monitoring electrochemical reactions during the operation of a solid-state battery using photoelectron spectroscopy at BESSY II. The results help to improve battery materials and design.
- From waste to value: The right electrolytes can enhance glycerol oxidationWhen biomass is converted into biodiesel, huge amounts of glycerol are produced as a by-product. So far, however, this by-product has been little utilised, even though it could be processed into more valuable chemicals through oxidation in photoelectrochemical reactors. The reason for this: low efficiency and selectivity. A team led by Dr Marco Favaro from the Institute for Solar Fuels at HZB has now investigated the influence of electrolytes on the efficiency of the glycerol oxidation reaction. The results can help to develop more efficient and environmentally friendly production processes.