Polymer colour converter with very high modulation bandwidth for visible light communications

We thank EPSRC for financial support from the UP-VLC Project Grant (EP/K00042X/1). I.D.W.S. and P.J.S. are Royal Society Wolfson Research Merit Award holders.For white light data communications, broad-band light emitting materials are required, whose emission can be rapidly modulated in intensity. We report the synthesis, photophysics and application of a novel semiconducting polymer for use as a high bandwidth colour converter, to replace commercial phosphors in white LEDs. The high modulation bandwidth (470 MHz) is 140 times higher than that measured using a conventional LED phosphor.Publisher PDFPeer reviewe

Cool to warm white light emission from hybrid inorganic/organic light-emitting diodes

The synthesis and characterisation of two novel organic down-converting molecules is disclosed, together with their performance as functional colour-converters in combination with inorganic blue light-emitting diodes (LEDs). Each molecule contains two fluorene-triphenylamine arms, connected to either a benzothiadiazole or bisbenzothiadiazole core. These molecules have been selected on the basis that they are free from absorption bands in the green region of the visible spectrum to maximise their performance and offer improvements compared with previous BODIPY-containing analogues. The inorganic InGaN/GaN LED emits at 444 nm, overlying the absorption of each of the organic molecules. The combination of the blue (inorganic) and yellow (organic) emission is shown to produce reasonable quality, white light-emitting hybrid devices for both down-converter molecules. Cool to warm white light is achieved for both molecules by increasing the concentration. An optimum colour rendering index (CRI) value of 66 is obtained for the mono-benzothiadiazole molecule. Also a high blue-to-white efficacy (defined as white luminous flux (lm)/blue radiant flux (W)) of 368 lm W$^{-1}$ is achieved, superseding the current phosphor converters of 200-300 lm W$^{-1}$. A comparison of these down-converting molecules to the older generation BODIPY-containing molecules is also provided.The authors would like to thank UK EPSRC (Grant No. EP/I012591/1 “Lighting the Future” and EP/L016982/1 “Next generation white LEDs using hybrid inorganic/organic semiconductor nanostructures for general illumination and wireless communication”) for financial support. DJW received funding through EPSRC's Manufacturing Fellowship in Gallium Nitride (EP/N01202X/1)

Star-shaped fluorene-BODIPY oligomers: versatile donor-acceptor systems for luminescent solar concentrators

Energy transfer in star-shaped donor–acceptor molecules reduces self-absorption in luminescent solar concentrators.N. J. L. K. D. is supported by the Cambridge Commonwealth European and International Trust, Cambridge Australian Scholarships and Mr Charles K Allen. R. W. M. acknowledges funding from the Initiative and Networking Fund of the Helmholtz Association. S. T. E. J. is supported by the Royal society. RGDT is supported by the EPSRC. D. C. thanks the Royal Society. PJS thanks the Royal Society for a Wolfson Research Merit Award. This work as supported by the EPSRC [EP/M005143/1, EP/M014797/1, EP/L012200/1]

Efficiency enhancement of small molecule organic solar cells using hexapropyltruxene as an interface layer

The quenching of excitons in organic solar cells can play a significant role in limiting their power conversion efficiency (PCE). In this article, we investigate the effect of a thin layer of hexapropyltruxene inserted at the interface between the electron donor boron subphthalocyanine chloride (SubPc) and its underlying hole contact in planar heterojunction solar cells. We find that a 3.8 nm hexapropyltruxene interlayer between the molybdenum oxide (MoOx) hole contact and SubPc is sufficient to improve PCE in SubPc/C60 fullerene solar cells from 2.6% to 3.0%, a ∼20% performance improvement. While the absorption stays roughly the same, the comparison of external and internal quantum efficiencies reveals a significant increase in SubPc's contribution to the current for light with wavelengths between 520 and 600 nm. Microstructure and surface morphology assessed with in situ Grazing-Incidence Wide-Angle X-Ray Scattering (GIWAXS) and Atomic Force Microscopy (AFM), are evaluated alongside in situ spectroscopic ellipsometry, and photoluminescence measurements. The microstructural investigations demonstrate changes to the surface and bulk of SubPc grown atop a hexapropyltruxene interlayer indicating that the latter acts as a template layer in a similar way as MoOx. However, the improvement in PCE is found to be mainly via reduced exciton quenching at the MoOx contact with the insertion of the hexapropyltruxene layer

A cross-linkable, organic down-converting material for white light emission from hybrid LEDs

Acknowledgements: The authors thank EPSRC for funding through grants EP/P02744X/2 and EP/R03480X/1. DJW acknowledges support from EPSRC fellowship (EP/N01202X/2).Cinnamate-functionalised organic green emissive molecules can be UV-cured to give physically stable polymer films for use in white light hybrid LEDs.</jats:p