Scientists from the RIKEN Cluster for Pioneering Research and RIKEN Center for Emergent Matter Science have succeeded, in collaboration with international partners, in creating an ultrathin organic solar cell that is both highly efficient and durable.
Using a simple post-annealing process, they created a flexible organic cell that degrades by less than 5 percent over 3,000 hours in atmospheric conditions and that simultaneously has an energy conversion ratio – a key indicator of solar cell performance – of 13 percent.
Organic photovoltaics are considered to be a promising alternative to silicon-based conventional films, being more environmentally friendly and cheap to produce. Ultrathin flexible solar cells are particularly attractive, as they could provide large power per weight and be used in a variety of useful applications such as powering wearable electronics and as sensors and actuators in soft robotics.
However, ultrathin organic films tend to be relatively efficient, typically having an energy conversion ratio of around 10 to 12 percent, significantly lower than the ratio in silicon cells, which can be as high as 25 percent, or of rigid organic cells, which can be up to around 17 percent.
Ultrathin films also tend to degrade rapidly under the influence of sunlight, heat, and oxygen. Researchers are trying to create ultrathin films that are both energy efficient and durable, but it is often a difficult tradeoff.
In research published in Proceedings of the National Academy of Sciences of the United States of America, the group succeeded in showing that an ultrathin cell can be both durable and efficient. The group began with a semiconductor polymer for the donor layer, developed by Toray Industries, Inc., and experimented with a new idea, of using a non-fullerene acceptor, increasing the thermal stability.
On top of this, they experimented with a simple post-annealing process, where the material was heated to 150 degrees Celsius after an initial annealing at 90 degrees. This step proved to be critical in increasing the durability of device by creating a stable interface between the layers.
According to Kenjiro Fukuda, one of the authors of the study, “By combining a new power generation layer with a simple post-annealing treatment, we have achieved both high energy conversion efficiency and long-term storage stability in ultra-thin organic solar cells.
“Our research shows that ultra-thin organic solar cells can be used to supply high power in a stable way over long periods of time, and can be used even under severe conditions such as high temperature and humidity. I very much hope that this research will contribute to the development of long-term stable power supply devices that can be used in wearable electronics such as sensors attached to clothes.”
|Thanks for being here;
We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain.
With the rise of Ad Blockers, and Facebook – our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don’t have a paywall – with those annoying usernames and passwords.
Our news coverage takes time and effort to publish 365 days a year.
If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
$5 Billed Once credit card or paypal
|SpaceDaily Monthly Supporter
$5 Billed Monthly paypal only
New type of indoor solar cells for smart connected devices
Uppsala, Sweden (SPX) Mar 05, 2020
In a future where most things in our everyday life are connected through the internet, devices and sensors will need to run without wires or batteries. In a new article in Chemical Science, researchers from Uppsala University present a new type of dye-sensitised solar cells that harvest light from indoor lamps. The Internet of Things, or IoT, refers to a network of physical devices and applications connected through the internet. It is estimated that by 2025, many facets of our lives will be media … read more