Pressure-Induced Detrapping from Self-Trapped Excitons to Free Excitons toward Enhanced Emission and Piezochromism in Ruddlesden–Popper (110)-Oriented Perovskites
Mirosław Mączka, Szymon Sobczak, Kinga Roszak, Daniel Linhares Militão Vasconcelos, Filip Dybała, Artur P. Herman, Robert Kudrawiec, Andrzej Katrusiak, Paulo T. C. Freire

TL;DR
This paper shows how pressure can change the light emission of a special perovskite material, shifting its color and brightness by altering its structure.
Contribution
The study reveals a pressure-induced detrapping process from self-trapped to free excitons in (110)-oriented perovskites, enhancing emission and enabling piezochromism.
Findings
Pressure increases STE emission intensity 6.4-fold up to 2.56 GPa in ACE2PbBr4 perovskites.
Higher pressures (up to 11.11 GPa) shift emission to free excitons, causing a color change from orange-yellow to greenish-blue.
Structural changes under pressure, observed via X-ray and Raman, explain the emission behavior and phase transitions.
Abstract
Two-dimensional (2D) lead halide perovskites are emerging as excellent materials for optoelectronic applications including light-emitting diodes, photovoltaics, and photodetectors, owing to their efficient excitonic emission originating from both self-trapped excitons (STEs) and free excitons (FEs). Recently, many efforts have been focused on enhancing the emission intensity, modulating the dominant emission mechanism, and establishing direct correlations between optical properties and underlying structural motifs. Across the hybrid organic–inorganic layers in 2D perovskites, the nanorange modulation of the density, stiffness, strain, and ionicity can be efficiently tuned by external stimuli, including the substrate–film strain. Here, we report a pressure-induced narrowing of the band gap and an enhancement of STE and FE emission in the topology of the (110)-oriented Ruddlesden–Popper…
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Taxonomy
TopicsPerovskite Materials and Applications · Organic and Molecular Conductors Research · Solid-state spectroscopy and crystallography
