Microscopic Perspective of Synergy between Localized Surface Plasmon Resonance and Disruption of Dye Aggregates in Metal Nanoparticle-Enhanced Fluorescence

The interaction of rose bengal (RB) aggregates with silver nanoparticles (AgNPs) is investigated to understand the factors that contribute toward metal nanopaticle enhanced fluorescence (MEF), such as reproducibility, spectral shift, and distortion. Various shapes and sizes of RB aggregates (spherical, rods, and fibrils) are formed upon preparing films from their solution in solvent with different polarities. These molecular aggregates are disrupted in the presence of AgNPs, resulting in different enhancement factors, not only because of MEF but also due to hindrance to aggregation-caused quenching. Microspectroscopic studies provide valuable insights into the microheterogeneity of these mixed aggregates. Interestingly, the excited state decay pathways remain the same at the nanosecond time scale for different emission wavelengths. Additionally, the lifetime distribution is very narrow due to the interaction of RB deaggregates with the plasmonic AgNPs

Buried Interface Passivation of Perovskite Solar Cells by Atomic Layer Deposition of Al2O3

Despite having long excited carrier lifetimes and high mobilities in hybrid halide perovskite materials, conventional (n-i-p) devices exhibit significant interfacial nonradiative recombination losses that are little understood but limit the radiative efficiency and the overall open-circuit potential. In this Letter, we reveal that the process of spiro-OMeTAD coating on perovskite gives rise to buried defect states, which are detrimental to the devices’ operational stability. We subsequently report a method to passivate these deleterious buried defect states by atomic layer deposition of Al2O3 through controlled precursor dosages on fully functional devices. The process results in notable improvements in the overall device performance, but the underlying root-cause analysis is what we essentially aimed to elucidate here. The reported passivation technique results in (a) an increase in the efficiency primarily due to an increase of VOC by ∼60–70 mV and consequently (b) enhanced photoluminescence and higher electroluminescence quantum efficiency and (c) overall device operational (MPPT) stability under ambient and, exclusively, even under high vacuum (>300 h) conditions, which is otherwise challenging.The authors thank Ministry of New and Renewable Energy (MNRE), Govt. of India for financial support. S.K.S. and D.D.S. thank Department of Science and Technology (DST), Govt. of India for financial support through a bilateral research grant. S.G. thanks University Grant Commission; T.B., D.P., and S.B. thank Council of Scientific and Industrial Research (CSIR); N.S. acknowledges Prime Minister Research Fellowship for student fellowship. D.D.S. thanks CSIR for the Bhatnagar Fellowship supporting a part of this research. A.C. acknowledges SERB (India, Grant No. EMR/2017/004878) for financial support