The key to chemical transformations
Catalysis is a field of chemistry that studies materials that can accelerate or bring about chemical transformations. Hu has distinguished himself through his pioneering work on the production of solar fuels and the synthesis of high-added-value molecules. The prize is awarded each year by the Swiss National Science Foundation (SNSF) on behalf of the International Latsis Foundation.
Novel approach
Hu, who was born in China and came to Switzerland in 2007, founded the Laboratory of Inorganic Synthesis and Catalysis at the École Polytechnique Fédérale de Lausanne (EPFL). He is known for his innovative approach, which consists of combining the concepts and methods associated with three different types of catalysis (homogeneous, heterogeneous and enzymatic), which traditionally have remained separate. This approach has led to unprecedented understanding of fundamental catalysis and enabled the discovery of new catalysts with properties superior to those of previous materials.
“I decided not to worry too much about barriers between the types, as long as they work and give interesting results”, says Hu, a professor at the EPFL's Institute of Chemical Sciences and Engineering. “I always try to introduce something new or unpredictable to my research, but that's not necessarily obvious. Scientists like things to happen logically, so when you suggest something unfamiliar or that's believed to be impossible, you may sound a little crazy.”
Accordingly, the 39-year-old Hu sought to model enzymes (enzymatic catalysis) as part of his research on solar fuels (heterogeneous catalysis). “It didn't work, but we discovered a very good, new type of catalyst”, explains Hu. Half of his research team is working on solar fuels.
“We use solar energy to split water into oxygen and hydrogen, because hydrogen is an excellent source of energy”, says Hu, who received his undergraduate degree in chemistry from Peking University. “We would like to use catalytic materials to store this energy in the form of chemical products.” Hu estimates that such a technology could become reality in 15 to 20 years.
At the heart of chemistry
Research on high-value-added molecules for chemical products is Hu's other major area of research. “We are focusing on catalysis based on elements that are abundant on Earth, like iron, copper and nickel”, says Hu, who did his postdoctoral research at the California Institute of Technology. “Until now, the chemical industry has mostly been working with precious metals like platinum, but these are rare and expensive. Abundant Earth elements are cheaper and have good potential, seeing as how they have been very little studied from that vantage.” These new molecules could later find use in the pharmaceutical, food-processing or even cosmetic industries.
Hu has amassed a remarkable number of publications for someone his age. “Scientific articles are really collaborative efforts”, he says. “I have been fortunate in finding students who are motivated and excited by the idea of investigating areas that are still relatively undiscovered.”
“I find it fascinating to be able to create new materials and to work in a field that has an impact on both nature and the living world”, says Hu. “Catalysis is at the heart of chemistry, but it goes unnoticed because it is so much a part of everyday life. Yet today it is more important than ever, especially for dealing with the energy challenges that humanity faces.”
Global chemist
Xile Hu was born in Putian, in south-eastern China, on 7 August 1978. He is a professor at the Institute of Chemical Sciences and Engineering at the École Polytechnique Fédérale de Lausanne (EPFL). After receiving his bachelor's degree in chemistry at Peking University in 2000, he left for the University of California, San Diego, where he received his master's degree in 2002 and his PhD in 2004. He then did postdoctoral research at the California Institute of Technology in Pasadena from 2005 to 2007. That same year, he accepted a position at EPFL, where he went on to found the Laboratory of Inorganic Synthesis and Catalysis. He has received numerous prizes and distinctions, including the Werner Prize from the Swiss Chemical Society.
Hu says he is “sometimes embarrassed that I don't fit the cliché of the scientist who spends all his free time in the laboratory”. He enjoys skiing and hiking in the mountains. Hu is married to a Swiss acupuncturist, with whom he has a three-month-old daughter.
Little noticed, but vital
Catalysis refers to the use of a substance to accelerate chemical transformations, or to bring about transformations that would not have occurred naturally. “Nearly 90% of chemical processes rely on catalysis at some point”, says Xile Hu, professor of chemistry at the École Polytechnique Fédérale de Lausanne (EPFL) and winner of the National Latsis Prize for 2017. “We would like them to enjoy even more widespread use, because a good catalyst makes it possible to avoid needless steps, in terms of cost as well as of time and energy.” Although catalysis is mainly employed in the chemical industry, it is equally important for humans and in nature. “Plants use biological catalysts for photosynthesis, whereas humans rely on enzymatic catalysis to metabolise the oxygen that they breathe”, says Hu. Moreover, anything to do with fermentation, such as the making of beer, yogurt or bread, depends on catalysis. Finally, the best-known catalysts are those used in cars. These catalysts transform engine emissions into non-toxic components that are then released into the air.
National Latsis Prize
Since 1983, the National Latsis Prize has been conferred annually by the Swiss National Science Foundation (SNSF) on behalf of the International Latsis Foundation, a non-profit organisation founded in 1975 and based in Geneva. It is awarded for outstanding scientific work by a Switzerland-based researcher under 40.
With CHF 100,000 in prize money, the National Latsis Prize is one of Switzerland's most prestigous scientific awards. There are also four University Latsis Prizes, each worth CHF 25,000, awarded by the Universities of Geneva and St, Gallen, and the Swiss Federal Institute of Technology in Zurich (ETHZ) and Lausanne (EPFL).
The award ceremony for the 34th National Latsis Prize will be held at Berne Town Hall on 11 January 2018. Journalists can register by sending an email to: com@snf.ch.
Contact
Prof. Xile Hu
École polytechnique fédérale de Lausanne
EPFL SB ISIC LSCI
BCH 3305 (Bldg. BCH)
CH-1015 Lausanne
Tel.: +41 21 693 97 81
E-mail: xile.hu@epfl.ch
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