Halide perovskites are a strong candidate for the next generation of photovoltaics. Chemical doping of halide perovskites is an established strategy to prepare the highest efficiency and most stable perovskite-based solar cells. In this study, we unveil the doping mechanism of halide perovskites using a series of alkaline earth metals. We find that low doping levels enable the incorporation of the dopant within the perovskite lattice, whereas high doping concentrations induce surface segregation. The threshold from low to high doping regime correlates to the size of the doping element. We show that the low doping regime results in a more n-type material, while the high doping regime induces a less n-type doping character. Our work provides a comprehensive picture of the unique doping mechanism of halide perovskites, which differs from classical semiconductors. We proved the effectiveness of the low doping regime for the first time, demonstrating highly efficient methylammonium lead iodide based solar cells in both n-i-p and p-i-n architectures.
Tin is the frontrunner for substituting toxic lead in perovskite solar cells. However, tin suffers the detrimental oxidation of SnII to SnIV. Most of reported strategies employ SnF2 in the perovskite precursor solution to prevent SnIV formation. Nevertheless, the working mechanism of this additive remains debated. To further elucidate it, we investigate the fluoride chemistry in tin halide perovskites by complementary analytical tools. NMR analysis of the precursor solution discloses a strong preferential affinity of fluoride anions for SnIV over SnII, selectively complexing it as SnF4. Hard X‐ray photoelectron spectroscopy on films shows the lower tendency of SnF4 than SnI4 to get included in the perovskite structure, hence preventing the inclusion of SnIV in the film. Finally, small‐angle X‐ray scattering reveals the strong influence of fluoride on the colloidal chemistry of precursor dispersions, directly affecting perovskite crystallization.
We
report on the chemical and electronic structure of cesium tin
bromide (CsSnBr3) and how it is impacted by the addition
of 20 mol % tin fluoride (SnF2) to the precursor solution,
using both surface-sensitive lab-based soft X-ray photoelectron spectroscopy
(XPS) and near-surface bulk-sensitive synchrotron-based hard XPS (HAXPES).
To determine the reproducibility and reliability of conclusions, several
(nominally identically prepared) sample sets were investigated. The
effects of deposition reproducibility, handling, and transport are
found to cause significant changes in the measured properties of the
films. Variations in the HAXPES-derived compositions between individual
sample sets were observed, but in general, they confirm that the addition
of 20 mol % SnF2 improves coverage of the titanium dioxide
substrate by CsSnBr3 and decreases the oxidation of SnII to SnIV while also suppressing formation of secondary
Br and Cs species. Furthermore, the (surface) composition is found
to be Cs-deficient and Sn-rich compared to the nominal stoichiometry.
The valence band (VB) shows a SnF2-induced redistribution
of Sn 5s-derived density of states, reflecting the changing SnII/SnIV ratio. Notwithstanding some variability
in the data, we conclude that SnF2 addition decreases the
energy difference between the VB maximum of CsSnBr3 and
the Fermi level, which we explain by defect chemistry considerations.
NaF/RbF-treated Cu(In,Ga)Se2 thin-film solar cell absorbers: distinct surface modifications caused by two different types of rubidium chemistry. ACS Applied Materials and Interfaces, 12(31), 34941-34948.
This study presents a novel numerical model for laser ablation and laser damage in glass including beam propagation and nonlinear absorption of multiple incident ultrashort laser pulses. The laser ablation and damage in the glass cutting process with a picosecond pulsed laser was studied. The numerical results were in good agreement with our experimental observations, thereby revealing the damage mechanism induced by laser ablation. Beam propagation effects such as interference, diffraction and refraction, play a major role in the evolution of the crater structure and the damage region. There are three different damage regions, a thin layer and two different kinds of spikes. Moreover, the electronic damage mechanism was verified and distinguished from heat modification using the experimental results with different pulse spatial overlaps.
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