Tuning the molecular ordering of COi8DFIC from flat-on and edge-on lamellae to Hand J-type p-p stacking results in broadened absorption spectrum and fine phase separation with the electron donor PTB7-Th, which promotes efficient exciton dissociation at the donor/acceptor interface together with enhanced and balanced carrier mobility, and leads to an unprecedented PCE of 13.8% of singlejunction, binary PTB7-Th:COi8DFIC solar cell.
Fluorination of conjugated molecules has been established as an effective structural modification strategy to influence properties, and has attracted extensive attention in organic solar cells (OSCs). Here, we have investigated optoelectronic and photovoltaic property changes of OSCs made of polymer donors with the non-fullerene acceptors (NFAs) ITIC and IEICO and their fluorinated counterparts IT-4F and IEICO-4F. Device studies show that fluorinated NFAs lead to reduced Voc but increased Jsc and FF, and therefore the ultimate influence to efficiency depends on the compensation of Voc loss and gains of Jsc and FF. Fluorination lowers energy levels of NFAs, reduces their electronic bandgaps and red-shifts the absorption spectra. The impact of fluorination on the molecular order depends on the specific NFA, with the conversion of ITIC to IT-4F reduces structural order, which can be reversed after blending with the donor PBDB-T. Contrastingly, IEICO-4F presents stronger p-p stacking after fluorination from IEICO, and this is further strengthened after blending with the donor PTB7-Th. The photovoltaic blends universally present a donor-rich surface region which can promote charge transport and collection towards anode in inverted OSCs. The fluorination of NFAs, however, reduces the fraction of donors in this donor-rich region, consequently encourage the intermixing of donor/acceptor for efficient charge generation.
The
development of scalable deposition methods for perovskite solar cell
materials is critical to enable the commercialization of this nascent
technology. Herein, we investigate the use and processing of nanoparticle
SnO2 films as electron transport layers in perovskite solar
cells and develop deposition methods for ultrasonic spray coating
and slot-die coating, leading to photovoltaic device efficiencies
over 19%. The effects of postprocessing treatments (thermal annealing,
UV ozone, and O2 plasma) are then probed using structural
and spectroscopic techniques to characterize the nature of the np-SnO2/perovskite interface. We show that a brief “hot air
flow” method can be used to replace extended thermal annealing,
confirming that this approach is compatible with high-throughput processing.
Our results highlight the importance of interface management to minimize
nonradiative losses and provide a deeper understanding of the processing
requirements for large-area deposition of nanoparticle metal oxides.
Self-assembled monolayers (SAMs) are becoming widely utilized as hole-selective layers in high-performance p-i-n architecture perovskite solar cells. Ultrasonic spray coating and airbrush coating are demonstrated here as effective methods to deposit MeO-2PACz; a carbazole-based SAM. Potential dewetting of hybrid perovskite precursor solutions from this layer is overcome using optimized solvent rinsing protocols. The use of air-knife gas-quenching is then explored to rapidly remove the volatile solvent from an MAPbI 3 precursor film spray-coated onto an MeO-2PACz SAM, allowing fabrication of p-i-n devices with power conversion efficiencies in excess of 20%, with all other layers thermally evaporated. This combination of deposition techniques is consistent with a rapid, roll-to-roll manufacturing process for the fabrication of large-area solar cells.
This is a repository copy of Correlating the electron-donating core structure with morphology and performance of carbon-oxygen-bridged ladder-type non-fullerene acceptor based organic solar cells.
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