HKU Engineering researchers unlock the key to efficient organic photovoltaics
A team of researchers led by Professor Philip C.Y. Chow from the Department of Mechanical Engineering at the University of Hong Kong (HKU) has made a breakthrough in the field of organic photovoltaics. Their research has revealed how the structure of organic photovoltaic (OPV) materials affect their performance, providing critical insights for future OPV material development. The discovery has been published in Energy & Environmental Science in an article entitled “Engineering ultrafast exciton dynamics to boost organic photovoltaic performance”.
What is organic photovoltaics (OPV)?
OPV is a promising emerging solar technology that could be used to power devices in a variety of innovative ways. Unlike traditional solar panels, which are made from rigid inorganic materials, OPV is made from organic (carbon-based) materials, giving them unique benefits. OPV is lightweight, flexible, affordable, and non-toxic, making it ideal for use in city buildings and in wearable devices.
While OPV is not yet as efficient as traditional solar panels, it has shown great potential. Over the past five years, its efficiency in converting solar energy into electricity has improved significantly, from around 10% to over 20%. This progress is largely attributed to the development of a series of new materials known as Y-type acceptors. However, the lack of full understanding by scientists regarding the workings of these molecules has impeded further advancements.
Discovery by the research team
Utilising advanced tools, Professor Chow’s research team has revealed how the structure of Y-type acceptors impacts their performance in OPV devices. The key findings are:
Key behaviors of excitons: When sunlight hits an OPV material, it generates excitons (electron-hole pairs bound by Coulombic force). In Y-type acceptors, excitons transition from less organised (disordered) regions of the material to more organised (ordered) regions. The team has found a way to track this rapid movement, which occurs incredibly fast within picoseconds, or trillionths of a second.
Better-organised molecules perform better: The researchers found that OPV materials with molecules that are neatly and uniformly packed enable excitons to move more quickly from disordered to ordered regions. The enhanced movement of excitons in Y-type acceptors is strongly linked to the improved solar conversion performance of the corresponding OPV devices.
The sweet spot for performance: Interestingly, the researchers discovered that Y-type acceptors perform optimally when the molecules are neither overly tightly packed nor too loosely packed. This “just right” (optimal) level of organisation results in a more uniform material, facilitating more efficient movement of excitons and enhancing the overall performance of OPV devices.