Curving Solar Cells Beyond the Planar Efficiency Limit

Curving surface is the feature of flexible electronics; however, fundamental theoretical research, such as the efficiency limit of curved optoelectronics significantly lags behind experimental works as well as the planar counterpart. Here, we propose a theoretical framework suitable for curved photovoltaics by developing a geometrically modified thermodynamic model of solar cell radiation. By considering singly and doubly curved structures, we reveal that the efficiency limit of solar cells, such as perovskite devices, increases with the mean curvature when nonradiative recombination processes are considered. The reduction in nonradiative voltage losses of the spherical and fiber-shaped solar cells originates from weaker photon recycling, which is primarily decided by the absorptance as well as the ratio of emission area to light-absorbing volume, revealing a negative correlation. Our work provides an in-depth understanding and theoretical guidance on flexible electronics.