Using state-of-the-art equipment, researchers in the Thermophysical Properties of Materials group from the University of the Basque Country (EHU) have analyzed the capacity of ultra-black copper cobaltate nanoneedles to effectively absorb solar energy. They showed that the new nanoneedles have excellent thermal and optical properties and are particularly suited to absorbing energy. This will pave the way toward concentrated solar power in the field of renewable energies.

The tests were carried out in a specialized lab that has the capacity to undertake high temperature research. The results were published in the journal Solar Energy Materials and Solar Cells.

Renewable energy of the future is concentrated solar power because it can be easily used to store thermal energy. Despite the fact that, historically, it is more expensive and complex than photovoltaic power, in recent years huge advances have taken place in this technology, and concentrated solar power plants are spreading across more and more countries as a resource for a sustainable future.

While most solar cells on the market today are based on silicon, energy engineers have recently been assessing the performance of alternative cells based on other photovoltaic (PV) materials. These alternative options include so-called organic solar cells (OSCs), lightweight and flexible cells that are based on organic semiconducting materials.

The operation of OSCs relies on a so-called active layer, a structure made of two different types of materials, referred to as donor and acceptor materials. Both materials absorb sunlight and generate excitons which dissociate into electrons and holes at the interface between donor and acceptor materials. Then holes are transported in donor materials, while the acceptors transport electrons and facilitate their flow through the device to generate electricity.

Compared to conventional silicon-based solar cells, OSCs could be more flexible, lighter, more affordable and easier to tailor for specific applications, for instance by changing their color or transparency. Nonetheless, the efficiency with which they convert solar energy into electricity remains significantly lower than that of commercially available photovoltaics (PVs).

A research team has developed an innovative parameter, FoMLUE, to evaluate the potential of photoactive materials for semi-transparent organic photovoltaics (ST-OPVs), paving the way for their widespread commercial applications.

A paper reporting the research, “Semitransparent organic photovoltaics with wide geographical adaptability as sustainable smart windows,” has been published in Nature Communications.

Transparent solar cells can be integrated into windows, screens and other surfaces, with immense potential for them to revolutionize the renewable energy sector. However, there are challenges to overcome, one of which is balancing transparency with power conversion efficiency.