INIS
quenching
100%
nanocrystals
100%
yields
100%
photoluminescence
100%
concentration
62%
surfaces
50%
energy transfer
37%
shells
25%
applications
25%
reduction
25%
refrigeration
25%
increasing
12%
single crystals
12%
mixtures
12%
phosphors
12%
lasers
12%
resonance
12%
values
12%
simulation
12%
absorption
12%
monte carlo method
12%
synthesis
12%
water
12%
ytterbium
12%
doped materials
12%
size
12%
experimental data
12%
photons
12%
concentration dependence
12%
Keyphrases
Photoluminescence Quantum Yield
100%
Photoluminescence Quenching
100%
Nanocrystals
100%
Yb3+
85%
PL Quenching
42%
Energy Transfer
28%
Concentration Quenching
28%
Optical Refrigeration
28%
Near-unity Photoluminescence Quantum Yield
28%
Large Reduction
14%
Bulk Single Crystal
14%
Förster Resonance Energy Transfer
14%
Concentration Dependence
14%
Short Axis
14%
Ytterbium-doped
14%
Used Material
14%
Physical Applications
14%
Nanophosphors
14%
Reaction Mixture
14%
Biological Applications
14%
Bioapplications
14%
Monte Carlo Simulation
14%
Laser Applications
14%
Undoped
14%
Nearest Neighbor
14%
Photon Upconversion
14%
Core-shell Nanocrystals
14%
All-source
14%
Yield Value
14%
Physics
Photoluminescence
100%
Nanocrystal
100%
Core
50%
Energy Transfer
37%
Refrigeration
25%
Ytterbium
12%
Monte Carlo Simulation
12%
Utilization
12%
Site
12%
Quality
12%
Water
12%
Laser Applications
12%
Increasing
12%
Single Crystal
12%
Concentration Dependence
12%
Medium
12%
Engineering
Quantum Yield
100%
Nanocrystal
100%
Surface
50%
Reduction
25%
Energy Engineering
25%
Application
12%
Reaction Mixture
12%
Resonance Energy
12%
Bioapplications
12%
Water
12%
Core-Shell
12%
Laser Application
12%
Nearest Neighbor
12%
Quenching
12%
Material Science
Nanocrystalline Material
100%
Photoluminescence
100%
Surface
50%
Materials
37%
Mixture
12%
Water
12%
Laser Application
12%
Ytterbium
12%
Single Crystal
12%
Phosphor
12%