Nobel Prize countdown

As students head back to the class room for a new term of exciting learning, the scientific community is gearing up for a major annual event, the announcement of the Noble Prizes.
With just days to go before the Nobel Prize in Chemistry is to be announced, there is much discussion (and possibly even a bit of betting) about who is likely to be this year's laureate.

Among the contenders this year are:

• Louis E. Brus (Columbia University) for the discovery of colloidal semiconductor nanocrystals (quantum dots)
• Akira Fujishima (University of Tokyo) for the discovery of photocatalytic properties of titanium dioxide (the Honda-Fujishima Effect)
• Masatake Haruta (Tokyo Metropolitan University) and Graham J. Hutchings (Cardiff University) for their discoveries of catalysis by gold

Quantum dots are semiconductors, but their electronic properties are related to the size and shape of the individual crystals. In general, the smaller a crystal is, the more energy is needed to excite the dot, which means that more energy is released when the crystal returns to its ground state. It is hoped that quantum dots will lead to practical quantum computing and increase the efficiency of photovoltaic cells. Quantum dots are being used in preference to some dyes in biological analyses because quantum dots are brighter and more stable.

While working on his Ph.D in 1967, Akira Fujishima exposed a titanium dioxide electrode to strong light and discovered that this catalyzed the decomposition of water into hydrogen and oxygen. This became known as the Honda-Fujishima Effect (Professor Kenichi Honda was Akira Fujishima's supervisor). Finding cheap, effective methods for providing hydrogen would enable the development of hydrogen as fuel.

In the 1980's Masatake Haruta showed that colloidal gold, gold clusters with diameters of 5 nanometers or less, could catalyze reactions involving oxygen gas.
Graham J Hutchings has extended the number of reactions  we now know of that can be catalyzed by gold. Hutchings has shown that primary alcohols can be oxidized to aldehydes using a gold-palladium/titanium dioxide combination without the need for a solvent. He has also developed the rapid synthesis of hydrogen peroxide, H₂O₂, from hydrogen and oxygen  without the formation of water as a by-product.