5 research outputs found
Recent advancements in plasmon-enhanced promising third-generation solar cells
The unique optical properties possessed by plasmonic noble metal nanostructures in consequence of localized surface plasmon resonance (LSPR) are useful in diverse applications like photovoltaics, sensing, non-linear optics, hydrogen generation, and photocatalytic pollutant degradation. The incorporation of plasmonic metal nanostructures into solar cells provides enhancement in light absorption and scattering cross-section (via LSPR), tunability of light absorption profile especially in the visible region of the solar spectrum, and more efficient charge carrier separation, hence maximizing the photovoltaic efficiency. This review discusses about the recent development of different plasmonic metal nanostructures, mainly based on Au or Ag, and their applications in promising third-generation solar cells such as dye-sensitized solar cells, quantum dot-based solar cells, and perovskite solar cells
Recent advancements in plasmon-enhanced visible light-driven water splitting
Recently, the combination of plasmonic noble metallic nanostructures with semiconductors for plasmon-enhanced visible light-driven water splitting (WS) has attracted considerable attention. This review first presents three prime enhancement mechanisms for plasmon-enhanced photocatalytic WS, and then some state-of-the-art representative studies are introduced according to different enhancement mechanisms. Furthermore, the design parameters of plasmonic-metal/semiconductor photocatalysts are discussed in detail, focusing on the effect of shape, size and geometric position of metallic nanostructures on the photocatalytic activity of visible light-driven WS. Finally, the challenges and perspectives for plasmon-enhanced solar WS are proposed
The role of crystallinity of the Nb<sub>2</sub>O<sub>5 </sub>blocking layer on the performance of dye-sensitized solar cells
The prevention of back electron transfer by inserting an energy barrier layer at the interface of a photo-anode is an effective method for improving the photovoltaic parameters in dye sensitised solar cells (DSSCs). In this study, phase a modified Nb2O5 blocking layer was inserted at the fluorine doped tin oxide (FTO)/TiO2 interface via a Rf magnetron sputtering process. For a critical tunnelling distance of -40 nm, the crystalline Nb2O5 blocking layer improved the efficiency close to 7% and outperformed the amorphous blocking layer by about 68%. The longer electron lifetime observed in DSSCs containing an inhomogeneous Nb2O5 layer indicates that trapping/de-trapping impedes the discharge of electrons to the TiO2 band edge. The origin of the longer electron lifetime is explained by formulating a theory from photovoltage decay measurements
Enhanced Long-term and Thermal Stability of Polymer Solar Cells in Air at High Humidity with the Formation of Unusual Quantum Dot Networks
Due
to the practical applications of polymer solar cells (PSCs),
their stability recently has received increasing attention. Herein,
a new strategy was developed to largely enhance the long-term and
thermal stability of PSCs in air with a relatively high humidity of
50–60% without any encapsulation. In this strategy, semiconductor
PbS/CdS core/shell quantum dots (QDs) were incorporated into the photoactive
blend of polyÂ(3-hexylthiophene) (P3HT) and phenyl-C<sub>61</sub>-butyric
acid methyl ester (PCBM). By replacing the initial ligands of oleic
acid with halide ligands on the surface of PbS/CdS QDs via solution-phase
ligand exchange, we were able to form unusual, continuous QD networks
in the film of P3HT:PCBM, which effectively stabilized the photoactive
layer. Air-processed PSCs based on the stabilized P3HT:PCBM film showed
excellent long-term stability under high humidity, providing over
3% of power conversion efficiency (PCE) simultaneously. Around 91%
of pristine PCE was retained after 30 days storage in high-humidity
air without encapsulation. This constitutes a remarkable improvement
compared to ∼53% retained PCE for the QD-free devices, which
can be ascribed to the efficient suppression of both PCBM aggregation
and oxidation of the thiophene ring in P3HT, thanks to the formation
of robust QD networks. Furthermore, the presence of QD networks was
able to enhance the stability of the P3HT:PCBM film against thermal
stress/oxidation under high-humidity environment (50–60%) as
well. The device kept 60% of pristine PCE after thermal treatment
for 12 h at 85 °C in air, which is more than twice higher than
that for the QD-free device. To the best of our knowledge, the work
represents the first unambiguous demonstration of the formation of
QD networks in the photoactive layer and of their important contribution
to the stability of PSCs. This strategy is highly promising for other
fullerene-based PSCs and opens a new avenue toward achieving PSCs
with high PCE and excellent stability