posted on 2017-02-07, 00:00authored byNoah J.
J. Johnson, Sha He, Shuo Diao, Emory M. Chan, Hongjie Dai, Adah Almutairi
Luminescence quenching
at high dopant concentrations generally
limits the dopant concentration to less than 1–5 mol% in lanthanide-doped
materials, and this remains a major obstacle in designing materials
with enhanced efficiency/brightness. In this work, we provide direct
evidence that the major quenching process at high dopant concentrations
is the energy migration to the surface (i.e., surface quenching) as
opposed to the common misconception of cross-relaxation between dopant
ions. We show that after an inert epitaxial shell growth, erbium (Er3+) concentrations as high as 100 mol% in NaY(Er)F4/NaLuF4 core/shell nanocrystals enhance the emission intensity
of both upconversion and downshifted luminescence across different
excitation wavelengths (980, 800, and 658 nm), with negligible concentration
quenching effects. Our results highlight the strong coupling of concentration
and surface quenching effects in colloidal lanthanide-doped nanocrystals,
and that inert epitaxial shell growth can overcome concentration quenching.
These fundamental insights into the photophysical processes in heavily
doped nanocrystals will give rise to enhanced properties not previously
thought possible with compositions optimized in bulk.