Critical role of dopant in NiO x hole transport layer for mitigating redox reactivity at NiO x /absorber interface in mixed cation perovskite solar cells

Redox chemistry transpiring at the interface of NiO hole transport layer (HTL) and perovskite absorber is a critical phenomenon leading to relatively low values of open circuit voltage ( ) and fill factor (FF), in turn hampering the overall device performance and stability. In this work, for the fir...

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Published in:Dalton transactions : an international journal of inorganic chemistry 2024-01, Vol.53 (2), p.781-797
Main Authors: Sudhakaran Menon, Vidya, Ganesan, Saraswathi, Raman, Rohith Kumar, Alagumalai, Ananthan, Krishnamoorthy, Ananthanarayanan
Format: Article
Language:English
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Summary:Redox chemistry transpiring at the interface of NiO hole transport layer (HTL) and perovskite absorber is a critical phenomenon leading to relatively low values of open circuit voltage ( ) and fill factor (FF), in turn hampering the overall device performance and stability. In this work, for the first time, the hard acid electronic nature of vanadium (V) dopant in nickel oxide HTL is opportunely exploited to mitigate the undesirable Lewis acid-base reactions occurring at the HTL/mixed-cation perovskite interface. The findings of the study show that vanadium doping results in improved interfacial energetics along with decreased loss, confirming that despite the increase in Ni /Ni ratio with the vanadium dopant, the redox reaction catalyzed by Ni ions is kept under check. Vanadium doping also aided in the realization of superior perovskite films with lower Urbach energy, which translated into one order increase in maximum photoinduced carrier generation rate per unit volume. Carrier dynamics investigations show fewer defect states (lower ) and trap-assisted recombination (lower diode ideality factor), which optimize the devices' photovoltaic performance. These benefits collectively contribute to low-loss charge transfer across the NiO /mixed-cation perovskite interface, which increases the relative efficiency by ∼30% for 5 wt% V-doped NiO devices compared to pristine NiO devices, augmented by an increase in device - parameters like open circuit voltage ( ), short circuit current density ( ), and fill factor (FF).
ISSN:1477-9226
1477-9234
DOI:10.1039/D3DT03012A