From 1995-2015, fullerene derivatives had been the dominating electron acceptors in organic solar cells (OSCs) owing to their performance superiority to other acceptors. However, the drawbacks of ...

Controlling organic semiconductor band gaps by electron-acceptor fluorination. ScienceDaily . Retrieved May 22, 2025 from www.sciencedaily.com / releases / 2018 / 10 / 181017080805.htm ...

During 1995-2015, fullerene derivatives had been the dominating electron acceptors in organic solar cells (OSCs) owing to their performance superior to other acceptors. However, the drawbacks of ...

They developed a new fluorinated fused-ring electron acceptor (FREA) with 3D stacking and exciton and charge transport. view more Recently, Professor Zhan Xiaowei's group from the College of ...

Now, materials called non-fullerene acceptors that can intrinsically generate ... Through a series of reactions called the electron transport chain, electrons are passed along in a sort ...

The cell is based on a new non-fullerene electron acceptor, which is said to be a new class of the Y6 non-fullerene acceptor that is widely used in research on organic solar cells. The scientists ...

Oxygen’s key role is to function as a terminal electron acceptor. In other words, it is like the positive terminal on a battery. Food (like carbohydrates) function as the negative terminal.

The researchers claim the fluorinated electron-acceptor unit, embedded in an organic thin film solar cell they developed, was 3.12% more efficient than an analogue non-fluorinated cell.