posted on 2016-03-03, 00:00authored byDmitry
A. Kislitsyn, Vancho Kocevski, Jon M. Mills, Sheng-Kuei Chiu, Christian
F. Gervasi, Benjamen N. Taber, Ariel E. Rosenfield, Olle Eriksson, Ján Rusz, Andrea M. Goforth, George V. Nazin
The
photophysical properties of silicon semiconductor nanocrystals
(SiNCs) are extremely sensitive to the presence of surface chemical
defects, many of which are easily produced by oxidation under ambient
conditions. The diversity of chemical structures of such defects and
the lack of tools capable of probing individual defects continue to
impede understanding of the roles of these defects in SiNC photophysics.
We use scanning tunneling spectroscopy to study the impact of surface
defects on the electronic structures of hydrogen-passivated SiNCs
supported on the Au(111) surface. Spatial maps of the local electronic
density of states (LDOS) produced by our measurements allowed us to
identify locally enhanced defect-induced states as well as quantum-confined
states delocalized throughout the SiNC volume. We use theoretical
calculations to show that the LDOS spectra associated with the observed
defects are attributable to Si–O–Si bridged oxygen or
Si–OH surface defects.