2 research outputs found
Silver Ions Direct Twin-Plane Formation during the Overgrowth of Single-Crystal Gold Nanoparticles
It is commonly agreed
that the crystalline structure of seeds dictates
the crystallinity of final nanoparticles in a seeded-growth process.
Although the formation of monocrystalline particles does require the
use of single-crystal seeds, twin planes may stem from either single-
or polycrystalline seeds. However, experimental control over twin-plane
formation remains difficult to achieve synthetically. Here, we show
that a careful interplay between
kinetics and selective surface passivation offers a unique handle
over the emergence of twin planes (in decahedra and triangles) during
the growth over single-crystalline gold nanoparticles of quasi-spherical
shape. Twinning can be suppressed under conditions of slow kinetics
in the presence of silver ions, yielding single-crystalline particles
with high-index facets
Interplay of Interfacial Layers and Blend Composition To Reduce Thermal Degradation of Polymer Solar Cells at High Temperature
The thermal stability
of printed polymer solar cells at elevated temperatures needs to be
improved to achieve high-throughput fabrication including annealing
steps as well as long-term stability. During device processing, thermal
annealing impacts both the organic photoactive layer, and the two
interfacial layers make detailed studies of degradation mechanism
delicate. A recently identified thermally stable poly[[4,8-bis[(2-ethylhexyl)oxy]benzo[1,2-<i>b</i>:4,5-<i>b</i>′]dithiophene-2,6-diyl][3-fluoro-2-[(2-ethylhexyl)carbonyl]thieno[3,4-<i>b</i>]thiophenediyl]]:[6,6]-phenyl-C<sub>71</sub>-butyric acid
methyl ester (PTB7:PC<sub>70</sub>BM) blend as photoactive layer in
combination with poly(3,4-ethylenedioxythiophene) polystyrene sulfonate
as hole extraction layer is used here to focus on the impact of electron
extraction layer (EEL) on the thermal stability of solar cells. Solar
cells processed with densely packed ZnO nanoparticle layers still
show 92% of the initial efficiency after constant annealing during
1 day at 140 °C, whereas partially covering ZnO layers as well
as an evaporated calcium layer leads to performance losses of up to
30%. This demonstrates that the nature and morphology of EELs highly
influence the thermal stability of the device. We extend our study
to thermally unstable PTB7:[6,6]-phenyl-C<sub>61</sub>-butyric acid
methyl ester (PC<sub>60</sub>BM) blends to highlight the impact of
ZnO on the device degradation during annealing. Importantly, only
12% loss in photocurrent density is observed after annealing at 140
°C during 1 day when using closely packed ZnO. This is in stark
contrast to literature and addressed here to the use of a stable double-sided
confinement during thermal annealing. The underlying mechanism of
the inhibition of photocurrent losses is revealed by electron microscopy
imaging and spatially resolved spectroscopy. We found that the double-sided
confinement suppresses extensive fullerene diffusion during the annealing
step, but with still an increase in size and distance of the enriched
donor and acceptor domains inside the photoactive layer by an average
factor of 5. The later result in combination with comparably small
photocurrent density losses indicates the existence of an efficient
transport of minority charge carriers inside the donor and acceptor
enriched phases in PTB7:PC<sub>60</sub>BM blends