Stimulated Emission using Weakly Confined Quantum Dots
Ivo Tanghe a b c, Margarita Samoli c, Isabella Wagner d, Servet Ataberk Cayan a c, Kai Chen d, Justin Hodgkiss d, Iwan Moreels c, Dries Van Thourhout b, Zeger Hens c, Pieter Geiregat a c
a NoLIMITS Center for Non-Linear Microscopy and Spectroscopy, Belgium, Ghent University, Gante, Belgium
b Photonics Research Group, Ghent University, Belgium, Technologiepark-Zwijnaarde, 126, Gent, Belgium
c Physics and Chemistry of Nanostructures, Department of Chemistry, Ghent University, Ghent, Belgium
d School of Chemical and Physical Sciences, Victoria University of Wellington, Wellington, New Zealand, PO Box 600, Wellington, New Zealand
Proceedings of International Conference on Emerging Light Emitting Materials (EMLEM22)
Materials for next generation LEDs and lasers:
Limasol, Cyprus, 2022 October 3rd - 5th
Organizers: Maksym Kovalenko, Maryna Bodnarchuk and Grigorios Itskos
Invited Speaker, Pieter Geiregat, presentation 055
DOI: https://doi.org/10.29363/nanoge.emlem.2022.055
Publication date: 15th July 2022

Nanostructured semiconductors, or quantum dots (QDs), are heavily investigated for their applications in light emission such as light emitting diodes and lasers. The premise of cost-effective solution processing of such devices based on nanocrystals has recently driven research towards electrically pumped population inversion in laser diode structures. Challenges however remain to achieve net light amplification in the cavity due to a balance between limited material gains and lossy electrical contacts. Further reductions in threshold current densities, mainly limited by the non-radiative cap of ca. 1 nanosecond on the gain lifetime, are also required to achieve stable operation. Finally, color tunability is limited to the red by the gain bandwidth of the red-emitting CdSe/CdS QDs or even core/shell nanoplatelets used.

Here, we show that weakly confined charge carriers in giant CdS quantum dots display disruptive optical gain metrics that could alleviate these remaining issues. Being active in the green part of the spectrum, their properties match and even outcompeting state-of-the-art colloidal materials in the red. Material gain coefficients up to 50.000 cm-1 combined with a broad gain window of 160 nm. Also, a very promising gain lifetimes close to 3 ns is found. Invoking a model of stimulated emission based on bulk semiconductor physics, we are able to explain all of these remarkable gain metrics, yet only if a large band gap renormalization effect is invoked. Our results show that weakly confined nanomaterials are excellent gain materials, combining straightforward wet chemical synthesis and the promise of solution processability with beyond state-of-the-art gain metrics.

 

 

 
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