Direct quantification of quasi-Fermi level splitting in organic semiconductor devices

TL;DR

This paper introduces an electro-modulated photoluminescence method to directly measure the quasi-Fermi level splitting in organic solar cells, enabling better understanding of non-radiative losses affecting device efficiency.

Contribution

The work presents a novel experimental technique for directly quantifying QFLS in organic devices, independent of device architecture and operational conditions.

Findings

The method accurately predicts QFLS in bulk organic solar cells.

QFLS measurements are consistent across different device architectures.

The approach helps distinguish intrinsic non-radiative losses from device-related effects.

Abstract

Non-radiative losses to the open-circuit voltage are a primary factor in limiting the power conversion efficiency of organic photovoltaic devices. The dominant non-radiative loss is intrinsic to the active layer and can be determined from the quasi-Fermi level splitting (QFLS) and the radiative thermodynamic limit of the photovoltage. Quantification of the QFLS in thin film devices with low mobility is challenging due to the excitonic nature of photoexcitation and additional sources of nonradiative loss associated with the device structure. This work outlines an experimental approach based on electro-modulated photoluminescence, which can be used to directly measure the intrinsic non-radiative loss to the open-circuit voltage; thereby, quantifying the QFLS. Drift-diffusion simulations are carried out to show that this method accurately predicts the QFLS in the bulk of the device regardless of device-related non-radiative losses. State-of-the-art PM6:Y6-based organic solar cells are used as a model to test the experimental approach, and the QFLS is quantified and shown to be independent of device architecture. This work provides a method to quantify the QFLS of organic solar cells under operational conditions, fully characterizing the different contributions to the non-radiative losses of the open-circuit voltage. The reported method will be useful in not only characterizing and understanding losses in organic solar cells, but also other device platforms such as light-emitting diodes and photodetectors.