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LUX dark matter detector

Detecting dark matter

The kind of matter and energy we can see and touch – whether it is in the form of atoms and molecules, or heat and light, only forms a tiny proportion of the content of the Universe, only about 5%. Over a quarter is dark matter, which is totally invisible but whose gravitational attraction can be detected; while over two thirds is dark energy, a force that pushes the Universe to expand ever faster.
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Reacting at the speed of light

12 August 2013

Anatase photocatalyst in action. Photo: O. Usher (UCL MAPS)

It might look like an Alka-Seltzer bubbling away, but far from releasing CO2, this experiment could hold within it a cure to our addiction to fossil fuels. Tiny bubbles of hydrogen stream from a disc of titania (TiO2), which is breaking down the water surrounding it under the influence of bright light. Once the technology is perfected, factories producing hydrogen fuel from sunlight and water could become a reality.

Photocatalysis – the process by which chemical reactions are triggered, enabled or powered by light – is a big area of research within UCL, with studies concentrating on its ability to produce clean fuels from water and self-cleaning surfaces that break down grease and grime by themselves.

In the reaction here, photons from the light source (which is just out of frame to the right of the picture) hit the surface of the titania disc, exciting electrons within the atomic structure These then react with the water molecules, splitting it into its constituents of hydrogen and oxygen. In this experiment, chemicals dissolved in the water prevent the formation of oxygen, which would otherwise recombine with the hydrogen.

There are a couple of major challenges which need to be addressed before this process can be scaled up to industrial levels.

Anatase photocatalyst in action (closeup, high contrast). Photo: O. Usher (UCL MAPS)

First, the photocatalysts need to be able to work with visible light. In the experiment pictured here, the light we actually see with our eyes is not contributing to the chemical reaction in any way; only the small proportion of ultraviolet is actually doing any work, meaning that the vast majority of the energy is wasted.

Second, the process needs to work with pure water, without any need for chemical additives which make the process more complex and expensive.

And finally, it needs to be made vastly more efficient: to produce useful quantities of fuel on scales that can be burned in engines or reacted in fuel cells, you need more than a fine stream of bubbles.

Scientists have recently taken a step towards better understanding of photocatalysts. A team of chemists at UCL solved a long-standing puzzle regarding titania, making the substance better understood than ever before.

Photo credit: O. Usher (UCL MAPS)

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High resolution images

Titania photocatalyst producing hydrogen

Titania photocatalyst producing hydrogen (high contrast)

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Page last modified on 12 aug 13 13:27