Abstract
Generation and recombination of electrons and holes in organic solar cells occurs via charge transfer states located at the donor/acceptor interface. The energy of these charge transfer states is a crucial factor for the attainable open-circuit voltage and its correct determination is thus of utmost importance for a detailed understanding of such devices. This work reports on drastic changes of electroluminescence spectra of bulk heterojunction organic solar cells upon variation of the absorber layer thickness. It is shown that optical thin-film effects have a large impact on optical out-coupling of luminescence radiation for devices made from different photoactive materials, in configurations with and without indium tin oxide. A scattering matrix approach is presented which accurately reproduces the observed effects and thus delivers the radiative recombination spectra corrected for the wavelength-dependent out-coupling. This approach is proven to enable the correct determination of charge transfer state energies.
Highlights
Generation and recombination of electrons and holes in organic solar cells occurs via charge transfer states located at the donor/acceptor interface
charge transfer (CT) states are crucial for the thorough analysis of organic solar cells as their energy and occupation determine the open-circuit voltage (VOC) and have a large impact on the achievable power conversion efficiency
An exact determination of the CT state energy is of utmost importance
Summary
Generation and recombination of electrons and holes in organic solar cells occurs via charge transfer states located at the donor/acceptor interface. The energy of these charge transfer states is a crucial factor for the attainable open-circuit voltage and its correct determination is of utmost importance for a detailed understanding of such devices. A scattering matrix approach is presented which accurately reproduces the observed effects and delivers the radiative recombination spectra corrected for the wavelength-dependent out-coupling This approach is proven to enable the correct determination of charge transfer state energies. Electroluminescence (EL) spectroscopy is suitable to examine CT complexes since EL is dominated by CT state emission[6,15]
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