Abstract
AbstractInterface recombination in a complex multilayered thin‐film solar structure causes a disparity between the internal open‐circuit voltage (VOC,in), measured by photoluminescence, and the external open‐circuit voltage (VOC,ex), that is, a VOC deficit. Aspirations to reach higher VOC,ex values require a comprehensive knowledge of the connection between VOC deficit and interface recombination. Here, a near‐surface defect model is developed for copper indium di‐selenide solar cells grown under Cu‐excess conditions. These cell show the typical signatures of interface recombination: a strong disparity between VOC,in and VOC,ex, and extrapolation of the temperature dependent q·VOC,ex to a value below the bandgap energy. Yet, these cells do not suffer from reduced interface bandgap or from Fermi‐level pinning. The model presented is based on experimental analysis of admittance and deep‐level transient spectroscopy, which show the signature of an acceptor defect. Numerical simulations using the near‐surface defects model show the signatures of interface recombination without the need for a reduced interface bandgap or Fermi‐level pinning. These findings demonstrate that the VOC,in measurements alone can be inconclusive and might conceal the information on interface recombination pathways, establishing the need for complementary techniques like temperature dependent current–voltage measurements to identify the cause of interface recombination in the devices.
Highlights
deep-level transient spectroscopy (DLTS) measurements revealed these defects are acceptor in nature. The presence of these acceptor defects in Cu-rich device lead to significant interface VOC deficit leading to lower efficiency and electronic barriers in device structure, which is not observed in Cu-poor device
To elucidate the root origin of interface VOC deficit, we have demonstrated two comprehensive models for Cu-rich copper indium diselenide (CISe) solar cells, which can be applied to other heterostructure solar cells as well
We have demonstrated that the presence of both a defective surface and a defective interface could be confirmed by temperature-dependent VOC,ex measurements
Summary
Near surface defects: Cause of deficit between internal and external open-circuit voltage in solar cells. Mohit Sood1 | Aleksander Urbaniak2 | Christian Kameni Boumenou1 | Thomas Paul Weiss1 | Hossam Elanzeery1,3 | Finn Babbe1,4 | Florian Werner1,5 | Michele Melchiorre1 | Susanne Siebentritt[1]. Funding information Luxembourg National Research Fund (FNR), Grant/Award Numbers: C15/MS/10386094/ CORRKEST, C14/MS/8267152 CURI-K, 11341159/SURPASS, 11244141, 15/10935404/MASSENA
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