Breakthrough in multifunctional solar cells

A team of researchers, including Vasilii Balanov, Jani Peräntie, Jaakko Palosaari, Suhas Yadav, and Yang Bai, has made an advancement in the field of multifunctional energy harvesting. Their latest study advances in understanding the photovoltaic effect in ferroelectric crystals. The article reports the team’s recent research results regarding improving the electric output of the bulk photovoltaic effect (BPVE) via manipulation of ferroelectric domains in oxide perovskite crystals. The title of the article is Study on Influence of AC Poling on Bulk Photovoltaic Effectin Pb(Mg1/3 Nb 2/3 )O3 -PbTiO3 Single Crystals.

It is a bit difficult for non-specialists and requires explanation.

“In ordinary solar cells, the mechanism of harvesting the solar energy and then converting them into green electricity is based on the formation of p-n junctions of semiconductors. While the p-n junction has been invented for more than a century, widely used in the silicon industry nowadays, the BPVE is a more recently discovered physical phenomenon from the 1960s-1970s. The BPVE does not rely on p-n junctions to work under solar energy. It forms its own ‘‘self-junction’’ and, theoretically, it may break the physical limit of the Shockley-Queisser limit that prevents single p-n junction-based solar cells from being more efficient”, clarifies associate professor Yang Bai from Microelectronics research unit.

Using BPVE in practice is challenging at the moment, as the output power of BPVE-based cells is still negligible compared to those of p-n junction-based photovoltaic cells. In this study, Bai’s team proves that by creating a stacked domain structure, a 35 % improvement on the output power of BPVE-based cells can be achieved. A domain is a submicron-sized region containing spontaneous polarizations orienting in the same direction, which can be switched by applying an external electric field.

The improvement of electric output from Bai’s BPVE device is achieved by applying an AC poling electric field, under which the microstructure (domains) inside the crystals will be better aligned compared to the situation under the conventionally used DC field. After removing the electric field, the domains stay at that better aligned state. The better aligned domains help to reduce recombination of electric charge carriers, and thus the energy conversion efficiency increases. The results of the work pave a way towards developing more efficient BPVE cells that can help to unlock multifunctionality in future photonic, computing, sensing and energy harvesting devices.

“The first concrete applications will be in small-scale sensing and computing devices, where in addition to the electric signals, we can input light of different wavelengths as an extra degree of freedom for operation. For example, we have previously proven the use of BPVE in filterless colour sensor. Other examples include components for neuromorphic computing and multi-source energy harvesters for IoT (internet of things) devices”, says Yang Bai.

Despite the breakthrough now achieved, there is still a lot of research work ahead. Yang is aware of the challenges and the future goals are clear.

“While we are advancing in the working mechanism inside the materials, the challenge still lies in the band gap of the materials, where we ideally need a material that simultaneously has a narrow band gap (to maximise visible light absorption) and a large spontaneous polarization (to maximize the open-circuit voltage). We have limited options for such materials. Most available materials nowadays only possess either a narrow band gap or a large spontaneous polarization, not both. In the near future, we will attempt to expand the material options”, muses associate professor Yang Bai on behalf of his whole group.

This study has been published with the support of The European Research Council. ERC Starting Grant awarded to assistant professor Yang Bai for the project UNIFY in 2022.

Read the article in The journal of Advanced Electronic Materials and look at the graphic with a caption:

"In article, Yang Bai and co-workers validate the hypothesis of improved bulk photovoltaic effect promoted by a stacked domain structure in bulk ferroelectric crystals. This hypothesis had only been demonstrated in epitaxial thin films and remained as an open question in other materials for over a decade."

More information about the research project in the news article Yang Bai received significant ERC funding.