Shape-Controlled Solution-Epitaxial Perovskite Micro-Crystal Lasers Rivaling Vapor Deposited Ones

Afify HA, Rehm V, Barabash A, These A, Zhang J, Osvet A, Schüßlbauer C, Thiel D, Ullrich T, Dierner M, Przybilla T, Will J, Spiecker E, Guldi DM, Brabec C, Heiß W (2022)

Publication Type: Journal article

Publication year: 2022

Journal

Advanced Functional Materials Wiley-VCH Verlag

DOI: 10.1002/adfm.202206790

Abstract

Epitaxial growth methods usually need dedicated equipment, high energy consumption to maintain pure vacuum conditions and evaporation of source materials, and elevated substrate temperatures. Solution epitaxial growth requires nothing of that but is rarely used because the achieved microstructures are of low quality, not homogeneous, and finally exhibit worse performances in devices. Here, an antisolvent-vapor-assisted-crystallization of metal-halide-perovskites as a method overcoming these disadvantages is demonstrated. The methylammonium lead tribromide exhibits van-der-Waals type of epitaxial growth on mica substrates, resulting in micro-crystallites whose shape can be controlled to be either triangular micro-prism or micro-cuboid. These micro-crystallites act as optical resonators supporting various optical modes and lasing is achieved under optical excitation with low thresholds and record high environmental stability. Selecting suitable resonators from a large variety of sizes allows control of mode spacing and finally mono-mode operation, considered to be an important feature of semiconductor laser devices. The achieved results are essentially competitive to those obtained by vapor phase epitaxial microstructures, highlighting that epitaxy of high-quality optoelectronic device structures is feasible by minimum technological efforts and energy consumption, which are of increasing importance considering issues such as global warming and the current energy crisis.

Authors with CRIS profile

Viktor Rehm Professur für Werkstoffwissenschaften (lösungsprozessierte Halbleitermaterialien) Anastasiia Barabash Institute Materials for Electronics and Energy Technology (i-MEET) Albert These Institute Materials for Electronics and Energy Technology (i-MEET) Jiyun Zhang Institute Materials for Electronics and Energy Technology (i-MEET) Andres Osvet Institute Materials for Electronics and Energy Technology (i-MEET) Christoph Schüßlbauer Lehrstuhl für Physikalische Chemie I Dominik Thiel Lehrstuhl für Physikalische Chemie I Tobias Ullrich Lehrstuhl für Physikalische Chemie I Martin Dierner Lehrstuhl für Werkstoffwissenschaften (Mikro- und Nanostrukturforschung) Thomas Przybilla Lehrstuhl für Werkstoffwissenschaften (Mikro- und Nanostrukturforschung) Johannes Will Lehrstuhl für Werkstoffwissenschaften (Mikro- und Nanostrukturforschung) Erdmann Spiecker Lehrstuhl für Werkstoffwissenschaften (Mikro- und Nanostrukturforschung) Dirk Michael Guldi Lehrstuhl für Physikalische Chemie I Christoph Brabec Institute Materials for Electronics and Energy Technology (i-MEET) Wolfgang Heiß Professur für Werkstoffwissenschaften (lösungsprozessierte Halbleitermaterialien)

Additional Organisation(s)

Graduiertenkolleg 2495 Energiekonvertierungssysteme: von Materialien zu Bauteilen (Energy Conversion Systems: From Materials to Devices) Lehrstuhl für Werkstoffwissenschaften (Mikro- und Nanostrukturforschung) Graduiertenkolleg 1896/2 In situ Mikroskopie mit Elektronen, Röntgenstrahlen und Rastersonden Interdisziplinäres Zentrum, Center for Nanoanalysis and Electron Microscopy (CENEM)

Related research project(s)

In-situ Characterization of Nanomaterials with Electrons, X-rays/Neutrons and Scanning Probes (GRK 1896) Oct. 1, 2013 - Sept. 30, 2022

How to cite

APA:

Afify, H.A., Rehm, V., Barabash, A., These, A., Zhang, J., Osvet, A.,... Heiß, W. (2022). Shape-Controlled Solution-Epitaxial Perovskite Micro-Crystal Lasers Rivaling Vapor Deposited Ones. Advanced Functional Materials. https://dx.doi.org/10.1002/adfm.202206790

MLA:

Afify, Hany A., et al. "Shape-Controlled Solution-Epitaxial Perovskite Micro-Crystal Lasers Rivaling Vapor Deposited Ones." Advanced Functional Materials (2022).

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