Probabilities for dopant pair-state formation in a nanocrystal: simulations and theory
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Publication date
2001-01-01
Authors
Suyver, J.F.
Meester, R.
Kelly, J.J.
Meijerink, A.
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DOI
Document Type
Preprint
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Abstract
For certain dopants, luminescence measurements allow one to distin-
guish between single-ion and pair-state dopant emission in a (semicon-
ductor) host. In a bulk crystal the concentration of each of these dopant-
states can be calculated from the dopant fraction present in the material,
and is found to correlate with luminescence measurements. However, for
a nanocrystalline host-lattice, these concentrations cannot be calculated
due to the difference in coordination numbers for ions at the surface (a
substantial fraction in nanocrystals) and in the bulk. Here simulations of
dopant pair-state distributions are presented for a zincblende nanocrystal.
The probability of finding at least one pair-state in the nanocrystal and
the percentage of dopants forming part of a pair-state were calculated
on the basis of a statistical average of 1 . 105 simulations for the same
crystal size and dopant concentration. Furthermore, the distribution of
nanocrystal lattice positions over the surface and the bulk of the crystal
are computed from the simulations and found to agree well with a first-
order theory. Finally, a closed-form approximation of the probabilities
(valid in any crystal lattice) and a rigorous upper bound for the error in
the approximation are discussed.