Does bulk recombination limit photovoltaic performance?

Non-radiative recombination in the perovskite bulk and at its interfaces prohibits the photovoltaic performance from reaching the Shockley-Queisser limit. While interfacial recombination has been widely discussed and demonstrated, bulk recombination and especially the influence of grain boundaries remain under debate.

How can hollow core nanofibers improve the performance of polymer solar cells?

Hollow core nanofibers can improve the efficiency in several ways: by increasing the electrical conductivity of the buffer layer, shortening the hole pathway to improve hole extraction, decreasing the surface roughness of the buffer layers, and improving the exciton generation 11. Photovoltaic performance of polymer solar cells.

Are hollow core nanofibers a buffer layer for organic solar cells?

In the field of organic solar cells with a nanofiber structure, we introduced hollow core nanofibers as a novel and effective buffer layer of organic solar cells.

Does grain size affect photovoltaic performance?

Garnett and co-workers reported that grain boundaries in perovskite films might lead to both detrimental and advantageous effects. Several reports linked increased grain size with improved photovoltaic performance, although a careful examination reveals conflicting origins for this improvement.

Are hollow core PANI nanofibers a good choice for solar cells?

The new morphology and nano-structuration of hollow core PANI nanofibers showed a better conductivity compared to PANI. Moreover, the presence of the novel hierarchical hollow core structure improved the transport of charge carriers, while enhancing the efficiency of polymer solar cells.

Does hollow Pani improve hole-collection efficiency?

The morphology of the prepared buffer layers for organic solar cells (OSCs) was examined by atomic force microscopy (AFM), and the final device photovoltaic tests showed that hollow PANI decreases the hole extraction route and improves hole-collection efficiency.