Combining experiments on luminescent centres in hexagonal boron nitride with the polaron model and ab initio methods towards the identification of their microscopic origin

The two-dimensional material hexagonal boron nitride (hBN) hosts luminescent centres with emission energies of ∼2 eV which exhibit pronounced phonon sidebands. We investigate the microscopic origin of these luminescent centres by combining calculations with non-perturbative open quantum system theor...

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Published inNanoscale Vol. 15; no. 34; pp. 14215 - 14226
Main Authors Fischer, Moritz, Sajid, Ali, Iles-Smith, Jake, Hötger, Alexander, Miakota, Denys I, Svendsen, Mark K, Kastl, Christoph, Canulescu, Stela, Xiao, Sanshui, Wubs, Martijn, Thygesen, Kristian S, Holleitner, Alexander W, Stenger, Nicolas
Format Journal Article
LanguageEnglish
Published England Royal Society of Chemistry 01.09.2023
The Royal Society of Chemistry
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Summary:The two-dimensional material hexagonal boron nitride (hBN) hosts luminescent centres with emission energies of ∼2 eV which exhibit pronounced phonon sidebands. We investigate the microscopic origin of these luminescent centres by combining calculations with non-perturbative open quantum system theory to study the emission and absorption properties of 26 defect transitions. Comparing the calculated line shapes with experiments we narrow down the microscopic origin to three carbon-based defects: C C , C C , and V C . The theoretical method developed enables us to calculate so-called photoluminescence excitation (PLE) maps, which show excellent agreement with our experiments. The latter resolves higher-order phonon transitions, thereby confirming both the vibronic structure of the optical transition and the phonon-assisted excitation mechanism with a phonon energy ∼170 meV. We believe that the presented experiments and polaron-based method accurately describe luminescent centres in hBN and will help to identify their microscopic origin.
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ISSN:2040-3364
2040-3372
2040-3372
DOI:10.1039/d3nr01511d