Luminescent Solar Concentrators

LSCs of various sizes and materials under Ultraviolet illumination

Luminescent Solar Concentrators (LSCs) are sheets of plastic or glass, doped with fluorescent materials, which can collect and concentrate light from large areas to their edges, as shown in Figure 1. The light can then be converted into electricity by solar cells installed at their edges. LSCs have attracted significant attention due to their ability to achieve high concentration of light, even diffuse.

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Figure 1 -听LSCs of various sizes and materials under Ultraviolet illumination

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Depending on the users' desires, LSCs can be designed in a range of colours, transparencies, shapes, and sizes. As such, LSCs can be integrated into a range of applications, from architecture and construction (building walls or windows) to sports and leisure (boat sails or tents) or consumer electronics (watch straps and phone cases). As we recently argued¹, LSC is a powerful photonic platform finding an ever-expanding range of applications beyond generating electricity, including in sensing, photochemistry, horticulture and even in optical communications.

In our group we research LSCs through a range of development stages:

Theory 鈥� We have explored the fundamental limits of LSC performance, investigating the thermodynamic principles of the technology².

Simulation 鈥� Our group has developed a Monte-Carlo methods ray-tracing model which underpins many of our activities. The simulation platform allows us to predict, design and optimise LSC devices, creating novel designs.

Efficiency enhancement 鈥� In combination with our simulation platform we have proposed a range of enhancement techniques to push LSC efficiencies towards commercial viability. These techniques include dye alignment³, plasmonics⁴, Forster energy transfer ⁵, and wavelength selective mirrors⁶.

Fabrication 鈥� With our in-house fabrication facilities听we put our ideas to practise with prototype devices, always considering the materials and techniques required for up-scaling and industrial commercialisation. For example, our studies into viable flexible LSCs can increase the range of possible applications and fabrication techniques ^7,8.听

Characterisation 鈥� We have a range state-of-the-art fabrication techniques which allow us to characterise and assess the performance of our developed devices

LSCs used as receivers in high-speed visible light communications systems9 and LSCs used in horticulture to promote plant growth10.

Figure 3 鈥� LSCs used as receivers in high-speed visible light communications systems⁹ and LSCs used in horticulture to promote plant growth¹⁰.

Our research is not limited to using LSCs solely for the purpose of solar collection. We believe the technology can be used in a cross-disciplinary manner and techniques can be transferred and extended to a range of applications including optical communications⁹, agriculture technology¹⁰ and medical sensing, Figure 3.

Representative publications

1.听Papakonstantinou, I., Portnoi, M. & Debijie, M. G. The hidden potential of Luminescent Solar Concentrators. Adv. Energy Mater. Accept. Press 2002883, 1鈥�13 (2020).

2.听Papakonstantinou, I. & Tummeltshammer, C. Fundamental limits of concentration in luminescent solar concentrators revised: the effect of reabsorption and nonunity quantum yield. Optica (2015). doi:10.1364/optica.2.000841

3.听Tummeltshammer, C., Taylor, A., Kenyon, A. J. & Papakonstantinou, I. Homeotropic alignment and F枚rster resonance energy transfer: The way to a brighter luminescent solar concentrator. J. Appl. Phys. 116, 173103 (2014).

4.听Tummeltshammer, C., Brown, M. S., Taylor, A., Kenyon, A. J. & Papakonstantinou, I. Efficiency and loss mechanisms of plasmonic Luminescent Solar Concentrators. Opt. Express (2013). doi:10.1364/oe.21.00a735

5.听Tummeltshammer, C. et al. On the ability of F枚rster resonance energy transfer to enhance luminescent solar concentrator efficiency. Nano Energy 32, 263鈥�270 (2017).

6.听Portnoi, M. et al. All-Silicone-based Distributed Bragg Reflectors for Efficient Flexible Luminescent Solar Concentrators. Nano Energy 70, 104507 (2020).

7.听Portnoi, M., Sol, C., Tummeltshammer, C. & Papakonstantinou, I. Impact of curvature on the optimal configuration of flexible luminescent solar concentrators. Opt. Lett. (2017). doi:10.1364/ol.42.002695

8.听Tummeltshammer, C., Taylor, A., Kenyon, A. J. & Papakonstantinou, I. Flexible and fluorophore-doped luminescent solar concentrators based on polydimethylsiloxane. Opt. Lett. (2016). doi:10.1364/ol.41.000713

9.听Portnoi, M. et al. Bandwidth Limits of Luminescent Solar Concentrators as Detectors in Free-Space Optical Communication Systems. Light Sci. Appl. 10, (2021).

10.听Xu, Z., Portnoi, M., Papakonstantinou, I., Micro-cone arrays enhance outcoupling efficiency in horticulture luminescent solar concentrators. arXiv preprint arXiv:2206.14766

听(2022).

Funding

Chinese Scholarship Council PhD studentship (2021-2024).
香港六合彩中特网 BEAMS Dean鈥檚 Award (2021-2024).
IntelGlazing, Intelligent functional coating with self-cleaning properties to improve the energy efficiency of the built environment. European Research Council, ERC-StG GA 679891 (2016-2022).
MARVEL, Multifunctional Polymer Light-Emitting Diodes with Visible Light Communications. EPSRC, EP/P006280/1 (2016-2020).
SOLAR-PLUS, Maximizing the efficiency of Luminescent Solar Concentrators by implanting resonant plasmonic nanostructures鈥�, FP7 programme, Marie-Curie, Career Integration Grant, No. 293567 (2011-2015).

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