13,205 research outputs found
Identification of fullerene-like CdSe nanoparticles from optical spectroscopy calculations
Semiconducting nanoparticles are the building blocks of optical nanodevices
as their electronic states, and therefore light absorption and emission, can be
controlled by modifying their size and shape. CdSe is perhaps the most studied
of these nanoparticles, due to the efficiency of its synthesis, the high
quality of the resulting samples, and the fact that the optical gap is in the
visible range. In this article, we study light absorption of CdSe
nanostructures with sizes up to 1.5 nm within density functional theory. We
study both bulk fragments with wurtzite symmetry and novel fullerene-like
core-cage structures. The comparison with recent experimental optical spectra
allows us to confirm the synthesis of these fullerene-like CdSe clusters
Excitonic effects in the optical properties of CdSe nanowires
Using a first-principle approach beyond density functional theory we
calculate the electronic and optical properties of small diameter CdSe
nanowires.Our results demonstrate how some approximations commonly used in bulk
systems fail at this nano-scale level and how indispensable it is to include
crystal local fields and excitonic effects to predict the unique optical
properties of nanowires. From our results, we then construct a simple model
that describes the optical gap as a function of the diameter of the wire, that
turns out to be in excellent agreement with experiments for intermediate and
large diameters.Comment: submitte
Interaction-induced topological properties of two bosons in flat-band systems
In flat-band systems, destructive interference leads to the localization of
non-interacting particles and forbids their motion through the lattice.
However, in the presence of interactions the overlap between neighbouring
single-particle localized eigenstates may enable the propagation of bound pairs
of particles. In this work, we show how these interaction-induced hoppings can
be tuned to obtain a variety of two-body topological states. In particular, we
consider two interacting bosons loaded into the orbital angular momentum
states of a diamond-chain lattice, wherein an effective flux may yield a
completely flat single-particle energy landscape. In the weakly-interacting
limit, we derive effective single-particle models for the two-boson
quasiparticles which provide an intuitive picture of how the topological states
arise. By means of exact diagonalization calculations, we benchmark these
states and we show that they are also present for strong interactions and away
from the strict flat-band limit. Furthermore, we identify a set of doubly
localized two-boson flat-band states that give rise to a special instance of
Aharonov-Bohm cages for arbitrary interactions
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