Monolithic perovskite/silicon tandem solar cell achieves record efficiency

A cross section through the tandem cell is shown by this SEM-image.

A cross section through the tandem cell is shown by this SEM-image. © HZB

A heterojunction silicon cell provides the base for the tandem cell. A very thin layer of transparent tin dioxide was deposited on this bottom cell, followed by 500 nm of perovskite as well as 200 nm of spiro-OMeTAD hole-conductor material. Thin MoO3 serves as a protective layer between this hole conductor and the transparent top electrode of ITO.

A heterojunction silicon cell provides the base for the tandem cell. A very thin layer of transparent tin dioxide was deposited on this bottom cell, followed by 500 nm of perovskite as well as 200 nm of spiro-OMeTAD hole-conductor material. Thin MoO3 serves as a protective layer between this hole conductor and the transparent top electrode of ITO. © S. Albrecht / HZB

Teams from the Helmholtz-Zentrum Berlin and École Polytechnique Fédérale de Lausanne, Switzerland, have been the first to successfully combine a silicon heterojunction solar cell with a perovskite solar cell monolithically into a tandem device. The hybrid tandem cell showed an efficiency of 18 per cent. That is the highest currently reported value for this type of device architecture. There are even prospects for the efficiency to reach as much as 30 per cent.

Organic-inorganic perovskite materials are one of the biggest surprises in solar cell research. In just six years, the efficiency of perovskite solar cells has increased five-fold; moreover, perovskite solar cells can be manufactured from solution and be cost-effectively printed on large areas in the future.

Perovskite with silicon: good team but difficultto combine

Because perovskite layers absorb light in the blue region of the spectrum very efficiently, it is useful to combine these with silicon layers that primarily convert long-wavelength red and near-infrared light. Nevertheless, the construction of these kinds of tandem cells in a monolithic stack of deposited layers has been difficult. This is because for high efficiency perovskite cells, it is usually required to coat the perovskite onto titanium dioxide layers that must be previously sintered at about 500 degrees Celsius. However, at such high temperatures, the amorphous silicon layers that cover the crystalline silicon wafer in silicon heterojunction degrades.

New functional layers

Now a team headed by Prof. Bernd Rech and Dr. Lars Korte at the HZB Institute for Silicon Photovoltaics in cooperation with HZB’s PVcomB and a group headed by Prof. Michael Graetzel at the École Polytechnique Fédérale de Lausanne (EPFL) are the first to have fabricated this kind of monolithic tandem cell. They were successful in depositing a layer of tin dioxide at low temperatures to replace the usually used titanium dioxide. A thin layer of perovskite could then be spin-coated onto this intermediate layer and covered with hole-conductor material. In addition, a crucial element in the device architecture is the transparent top contact. Typically,  metal oxides are deposited by sputtering, but this would destroy the sensitive perovskite layer as well as the hole-conductor material. Therefore, the team from HZB modified the fabrication process and incorporated a transparent protective layer.

18 percent and high open circuit voltage

At 18 percent, this tandem cell attained an efficiency level that is nearly 20 percent higher than the efficiency of individual cells. The open-circuit voltage is 1.78 volts. “At that voltage level, this combination of materials could even be used for the generation of hydrogen from sunlight”, says Dr. Steve Albrecht, lead author of the paper that has now appeared in the renowned journal Energy & Environmental Science.

Additional light catching structures could increase efficiencies up to 30 percent

Steve Albrecht, a postdoc in the group of Bernd Rech, developed the device design of the tandem cell and is coordinating the collaboration with EPFL. “The 18 per-cent efficiency we measured is certainly very good, but light is still being lost at the surface in the present architecture”, he explains and is planning further improvements. A textured foil on the front side might be able to catch this light and couple it into the cell, which would further increase the cell’s efficiency. The heterojunction silicon solar cell that simultaneously functions as the bottom cell and the substrate for the perovskite top cell offers further potential for improvement. “This perovskite-silicon tandem cell is presently still being fabricated on a polished silicon wafer. By texturing this wafer with light-trapping features, such as random pyramids, the efficiency might be increased further to 25 or even 30 per cent”, says Dr. Lars Korte, head of the silicon heterojunction solar cell group at the Institute for Silicon Photovoltaics.

Integration into existing technologies

But almost more important than the maximum efficiency is the integration into existing technologies. “Silicon technology currently dominates 90 percent of the market, which means there are many established production facilities for silicon cells”, says Prof. Bernd Rech. “The perovskite layers could considerably increase the efficiency level. To achieve this, the fabrication techniques only need to be supplemented with a few more production steps. For that reason, our work is also extremely interesting for industry. However, the problems of long-term stability and the lead content of perovskite solar cells still need to be solved in future research.”


Monolithic Perovskite/Silicon-Heterojunction Tandem Solar Cells Processed at Low Temperature
Steve Albrecht,   Michael Saliba,   Juan Pablo Correa Baena,   Felix Lang,   Lukas Kegelmann,   Mathias Mews,   Ludmilla Steier,   Antonio Abate,   Joerg Rappich,   Lars Korte,   Rutger Schlatmann,   Nazeeruddin, Mohammad K.,   Anders Hagfeldt,   Michael Grätzel and   Bernd Rech  
Energy Environ. Sci., 2015, DOI: 10.1039/C5EE02965A

arö


You might also be interested in

  • Best Innovator Award 2023 for Artem Musiienko
    News
    22.03.2024
    Best Innovator Award 2023 for Artem Musiienko
    Dr. Artem Musiienko has been awarded a special prize for his groundbreaking new method for characterising semiconductors. At the recent annual conference of the Marie Curie Alumni Association (MCAA) in Milan, Italy, he received the MCAA Award for the best innovation. Since 2023, Musiienko has been carrying out his research project with a postdoctoral fellowship from the Marie Sklodowska Curie Actions in Antonio Abate's department, Novel Materials and Interfaces for Photovoltaic Solar Cells (SE-AMIP).
  • The future of BESSY
    News
    07.03.2024
    The future of BESSY
    At the end of February 2024, a team at HZB published an article in Synchrotron Radiation News (SRN). They describe the next development goals for the light source as well as the BESSY II+ upgrade programme and the successor source BESSY III.

  • 14 parameters in one go: New instrument for optoelectronics
    Science Highlight
    21.02.2024
    14 parameters in one go: New instrument for optoelectronics
    An HZB physicist has developed a new method for the comprehensive characterisation of semiconductors in a single measurement. The "Constant Light-Induced Magneto-Transport (CLIMAT)" is based on the Hall effect and allows to record 14 different parameters of transport properties of negative and positive charge carriers. The method was tested now on twelve different semiconductor materials and will save valuable time in assessing new materials for optoelectronic applications such as solar cells.