The novel solar cells are manufactured using a laser beam evaporation process; here is a picture of the resulting plasma. (Foto: Lutz Mühlenbein)
  • A new architectural method used to develop special solar cells could significantly increase their efficiency.
  • Not only are the cells made up of thin layers, but they also consist of specifically arranged nanoblocks.
  • The new architecture actually increased the cell's electrical output by a factor of five.

A new method for constructing special solar cells could significantly increase their efficiency. Not only are the cells made up of thin layers, but they also consist of specifically arranged nanoblocks.

This has been shown in a new study by an international research team led by the Martin Luther University Halle-Wittenberg (MLU), which was published in the scientific journal Nano Letters.

Commercially available solar cells are mostly made of silicon.

“Based on the properties of silicon it’s not feasible to say that their efficiency can be increased indefinitely,” says Dr Akash Bhatnagar, a physicist from the Centre for Innovation Competence (ZIK) “SiLi-nano” at MLU. His research team is therefore studying the so-called anomalous photovoltaic effect which occurs in certain materials.

The anomalous photovoltaic effect does not require a p-n junction which otherwise enables the flow of current in silicon solar cells. The direction of the current is determined at the atomic level by the asymmetric crystal structure of the corresponding materials. These materials are usually oxides, which have some crucial advantages: they are easier to manufacture and significantly more durable.

However, they often do not absorb much sunlight and have a very high electrical resistance. “In order to utilise these materials and their effect, creative cell architectures are needed that reinforce the advantages and compensate for the disadvantages,” explains Lutz Mühlenbein, lead author of the study.

In their new study, the physicists introduced a novel cell architecture, a so-called nanocomposite.

They were supported by teams from the Bergakademie Freiberg, the Leibniz Institute of Surface Modification in Leipzig and Banaras Hindu University in India. In their experiment, the researchers stacked single layers of a typical material only a few nanometres in thickness on top of one another and offset them with nickel oxide strips running perpendicularly.

“The strips act as a fast lane for the electrons that are generated when sunlight is converted into electricity and which are meant to reach the electrode in the solar cell,” Bhatnagar explains. This is precisely the transport that would otherwise be impeded by the electrons having to traverse each individual horizontal layer.

The new architecture actually increased the cell’s electrical output by a factor of five. Another advantage of the new method is that it is very easy to implement.

“The material forms this desired structure on its own. No extreme external conditions are needed to force it into this state,” says Mühlenbein. The idea, for which the researchers have now provided an initial feasibility study, could also be applied to materials other than nickel oxide. Follow-up studies now need to examine if and how such solar cells can be produced on an industrial scale.

Publication Referenced in the Article:

Lutz Mühlenbein, Chandra Bhal Singh, Andriy Lotnyk, Cameliu Himcinschi, Yeseul Yun, Niranjan Ramakrishnegowda, David S. Knoche, Xinye Li, Akash Bhatnagar. Nanocomposites with Three-Dimensional Architecture and Impact on Photovoltaic Effect. Nano Letters, 2020; 20 (12): 8789 DOI: 10.1021/acs.nanolett.0c03654

Editorial Team
The Editorial Team comprises a diverse and talented team of writers, researchers and subject matter experts equipped with data and insights to deliver useful news updates. We are experts with the mission to inform, educate and inspire the industry. We are passionately curious, enthusiastic, and motivated to positively impact the world. Send us a tip via hello @ pvbuzz [dot] com.

Wells Fargo to install 30MW of solar rooftop, carport and ground mount systems at its locations in seven states

Previous article

Quebec’s HPQ Silicon renews agreement to pursue development of silicon materials for energy storage and hydrogen production

Next article

You may also like


Comments are closed.