Osaka, Japan – Harnessing the power of the sun is vital for a clean, green future. To do so, we need optoelectronic devices, like solar cells, that can convert light into electricity efficiently. Now, a team led by Osaka University has discovered how to further improve device efficiency: by controlling how light-absorbing molecules stack together.
Organic optoelectronic devices, such as organic solar cells, are becoming increasingly sought after for their inherent advantages, e.g., flexibility or light weight. Their performance depends on how well their light-absorbing organic molecules convert light energy into 'free-charge carriers', which carry electric current. The energy needed to generate the free-charge carriers is referred to as 'exciton-binding energy'.
The lower the exciton-binding energy, the easier it is to generate free-charge carriers, and thus the better the device performance. However, we still struggle to design molecules with low exciton-binding energy in a solid state.
Upon deeper inspection, the research team found that the exciton-binding energy of solid materials is affected by how their molecules stack together, which is referred to as aggregation.
"We synthesized two types of similar star-shaped molecules, one with a flexible center and the other with a rigid center," explains lead author Hiroki Mori. "The individual molecules behaved similarly when they were dispersed in a solution, but quite differently when they were stacked together in thin solid films."
The difference in behavior is due to the rigid molecules stacking together well, like plates, whereas the flexible molecules do not. In other words, when in a solid state, the rigid molecule has a much lower exciton-binding energy than the flexible molecule. To verify this, the team built a single-component organic solar cell and a photocatalyst using each molecule. The solar cell and photocatalyst made of the rigid molecule showed impressive performance because their low exciton-binding energy led to a high generation of free-charge carriers.
"Our findings, that making molecules that aggregate well can decrease the exciton-binding energy, are really exciting," says senior author Yutaka Ie. "This could provide us with a new way to design more efficient optoelectronic devices."
The team's findings show that the interaction between molecules in a solid is important for device performance, and that the design of molecules for high-performance optoelectronic devices should look beyond individual molecular properties. This new way of decreasing exciton-binding energy could underpin the driving mechanisms and architecture of the next generation of optoelectronic devices.
