posted on 2018-09-07, 15:35authored byAlexander W. Achtstein, Oliver Marquardt, Riccardo Scott, Mohamed Ibrahim, Thomas Riedl, Anatol V. Prudnikau, Artsiom Antanovich, Nina Owschimikow, Jörg K. N. Lindner, Mikhail Artemyev, Ulrike Woggon
We investigate the impact of shell
growth on the carrier dynamics
and exciton–phonon coupling in CdSe–CdS core–shell
nanoplatelets with varying shell thickness. We observe that the recombination
dynamics can be prolonged by more than one order of magnitude, and
analyze the results in a global rate model as well as with simulations
including strain and excitonic effects. We reveal that type I band
alignment in the hetero platelets is maintained at least up to three
monolayers of CdS, resulting in approximately constant radiative rates.
Hence, observed changes of decay dynamics are not the result of an
increasingly different electron and hole exciton wave function delocalization
as often assumed, but an increasingly better passivation of nonradiative
surface defects by the shell. Based on a global analysis of time-resolved
and time-integrated data, we recover and model the temperature dependent
quantum yield of these nanostructures and show that CdS shell growth
leads to a strong enhancement of the photoluminescence quantum yield.
Our results explain, for example, the very high lasing gain observed
in CdSe–CdS nanoplatelets due to the type I band alignment
that also makes them interesting as solar energy concentrators. Further,
we reveal that the exciton-LO-phonon coupling is strongly tunable
by the CdS shell thickness, enabling emission line width and coherence
length control.