Sammanfattning
This work has presented new ways of using modulation spectroscopies and applied these to study samples. The main focus has been on continuouswave photoinduced absorption (cwPA). As a contact-free method, cwPA can help researchers in identifying and characterizing good candidates for solar cells without having to construct complete devices. Using an arbitrary reaction order δ, I have generalized the methods for characterizing recombination in cwPA-data. This yielded the ω1/(δ−1) dependence on modulation frequency ω for the quadrature at low frequencies with square-wavemodulation. This expression was used to distinguish between trap-assisted and twodimensional Langevin recombination in films of PBTTT:PC60BM with different blend ratios. I also showed that for trap-assisted recombination with an exponential trap distribution the expression depends on the characteristic energy Ech as ωkT/Ech.
Using a wide span of frequencies and sinusoidal modulation, I extracted generation rates and charge carrier lifetimes from cwPA for a range of temperatures. This revealed distinctly different temperature-dependent generation curves for P3HT:ICBA and PTB7:PCBM. I have described and motivated the procedures necessary to achieve reliable results at high frequencies, especially for slow photodetectors.
Furthermore, I have presented a new type of modulation spectroscopy, electromodulated-photoluminescence quantum efficiency,which can be used to gain access to the quasi Fermi level splitting at open circuit conditions. Combining one photovoltaic material with a range of different contact materials, we showed that the method measures the same QFLS over all devices, despite variations in the open-circuit voltage. The new method offers a way to characterize different losses occuring in solar cells, aiding researchers in optimizing device design.
Using a wide span of frequencies and sinusoidal modulation, I extracted generation rates and charge carrier lifetimes from cwPA for a range of temperatures. This revealed distinctly different temperature-dependent generation curves for P3HT:ICBA and PTB7:PCBM. I have described and motivated the procedures necessary to achieve reliable results at high frequencies, especially for slow photodetectors.
Furthermore, I have presented a new type of modulation spectroscopy, electromodulated-photoluminescence quantum efficiency,which can be used to gain access to the quasi Fermi level splitting at open circuit conditions. Combining one photovoltaic material with a range of different contact materials, we showed that the method measures the same QFLS over all devices, despite variations in the open-circuit voltage. The new method offers a way to characterize different losses occuring in solar cells, aiding researchers in optimizing device design.
Originalspråk | Engelska |
---|---|
Handledare |
|
Utgivningsort | Turku |
Förlag | |
Tryckta ISBN | 978-952-12-4365-3 |
Elektroniska ISBN | 978-952-12-4366-0 |
Status | Publicerad - 2024 |
MoE-publikationstyp | G5 Doktorsavhandling (artikel) |