Can nanostructured fluorescent systems be efficient luminophores for LSC applications?

The superior fluorescence intensity of SiLRNP-PDMS LSCs with respect to LR305-PDMS LSCs further confirms the potential of such LR305-containing nanostructured fluorescent systems as efficient luminophores for LSC applications. Fig. 7.

Can nanostructured luminophores be used in luminescent solar concentrators?

The nanostructured luminophores are based on hybrid core-shell silica nanoparticles. Such nanoparticles exhibit enhanced luminescence quantum yield and photostability. Their use as luminophores in luminescent solar concentrators (LSCs) is demonstrated. The obtained LSCs exhibit high efficiency and prolonged stability.

Are nanostructured luminescent species emissive fluorophores in thin-film LSC devices?

In conclusion, novel nanostructured luminescent species based on hybrid core-shell fluorescent NPs featured by enhanced LQY and photostability were synthetized, characterized and used as highly emissive fluorophores in thin-film LSC devices.

Are luminescent solar concentrators a viable spectral conversion technology?

The obtained LSCs exhibit high efficiency and prolonged stability. Luminescent solar concentrators (LSCs) represent a viable spectral conversion technology to maximize sunlight harvesting while promising to reduce the current gap for integration of solar cells into the built environment.

Can highly luminescent nanostructures reduce Dye aggregation?

This result provides a first indication of the viability of the proposed strategy to obtain highly luminescent nanostructures and suggests a significant reduction of dye aggregation phenomena within the NPs.

Do azo-bf2 photoswitches store and release energy during visible light irradiation?

We present here a group of Azo-BF2 photoswitches that store and release energy in response to visible light irradiation. Unmodified Azo-BF2 switches have a planar structure with a large π-conjugation system, which hinders E–Z isomerization when in a compacted state.