posted on 2007-10-31, 00:00authored byVladimir Protasenko, Stanislav Gordeyev, Masaru Kuno
Single-molecule optical experiments carried out in conjunction with externally applied electric
fields show deliberate spatial and intensity control over CdSe nanowire (NW) emission. In particular, by
applying external fields to electrically isolated (single) NWs, their emission can be localized in areas of the
wire closest to the positive electrode. In a few cases, the resulting emission intensity increases over the
corresponding zero-field value by nearly an order of magnitude. More often than not, factors of 2−3 are
seen. Reversing the field polarity causes the emission to localize in opposite regions of the wire. Emission
from individual NWs can therefore be modulated. Complementary ac electric field measurements show
that the effect persists up to 500 kHz. To explain the phenomenon, the effective passivation of surface
trap states by mobile carriers is speculated. This, in turn, causes local changes in the NW emission quantum
yield (QY). To verify the presence of such mobile charges, both ensemble and single NW bundle
electrophoresis experiments are conducted. By investigating subsequent NW rotational and translational
dynamics, an estimate for the number of mobile carriers is determined. A lower limit (best case) linear
charge density of ∼0.45−1.2 mobile electrons per micrometer of the wire is obtained. Apart from self-consistently explaining the field-induced NW emission modulation, the resulting data and subsequent analysis
also suggests that the same mobile carriers may be the root cause of NW emission intermittency.
Furthermore, given the ubiquity of stray charges, the resulting hypothesis may have additional applicability
toward explaining blinking in other systems, a problem of current interest especially within the context of
colloidal QDs.