Spatial–temporal spectroscopy characterizations and electronic structure of methylammonium perovskites

Spatial–temporal spectroscopy characterizations and electronic structure of methylammonium perovskites

Using time-resolved laser-scanning confocal microscopy and ultrafast optical pump/THz probe spectroscopy, we measure photoluminescence (PL) and THz-conductivity in perovskite micro-crystals and films. PL quenching and lifetime variations occur from local heterogeneity. Ultrafast THz-spectra measure...

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Veröffentlicht in:MRS communications 2018-09, Vol.8 (3), p.961-969
Hauptverfasser: Liu, Zhaoyu, Bhamu, K. C., Luo, Liang, Shah, Satvik, Park, Joong-Mok, Cheng, Di, Long, Men, Biswas, Rana, Fungara, F., Shinar, Ruth, Shinar, Joseph, Vela, Javier, Wang, Jigang
Format: Artikel
Sprache:eng
Schlagworte:
Binding energy
Biomaterials
Characterization and Evaluation of Materials
Dielectric strength
Electronic structure
Excitons
Materials Engineering
Materials Science
Microcrystals
Nanotechnology
Perovskites
Phase transitions
Photoluminescence
Photovoltaic cells
Polymer Sciences
Research Letter
Research Letters
Rydberg states
Semiconductors
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Zusammenfassung:Using time-resolved laser-scanning confocal microscopy and ultrafast optical pump/THz probe spectroscopy, we measure photoluminescence (PL) and THz-conductivity in perovskite micro-crystals and films. PL quenching and lifetime variations occur from local heterogeneity. Ultrafast THz-spectra measure sharp quantum transitions from excitonic Rydberg states, providing weakly bound excitons with a binding energy of ~13.5 meV at low temperatures. Ab-initio electronic structure calculations give a direct band gap of 1.64 eV, a dielectric constant of ~18, heavy electrons, and light holes, resulting in weakly bound excitons, consistent with the binding energies from the experiment. The complementary spectroscopy and simulations reveal fundamental insights into perovskite light-matter interactions.
ISSN:2159-6859
2159-6867
DOI:10.1557/mrc.2018.114