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Public release date: 20-Feb-2013[ | E-mail |
Share ] Contact: Jun.-Prof. Dr. Radim Bernek
radim.beranek@rub.de
49-234-322-9431
Ruhr-University Bochum
EU supports project '4G-PHOTOCAT' with 3.7 million Euro funding
Only light, aerial oxygen, and a catalyst are needed to remove pollutants from water. RUB researchers led by Prof. Radim Bernek collaborate with colleagues from seven different countries in order to develop a photocatalyst that is efficient enough to be profitable. For that purpose, they combine sunlight-absorbing semiconductors and nanostructured materials which they optimize for electron transfer processes. The aim is to implement the newly developed photocatalysts into a liquid paint with which photoreactors can easily be coated. The EU supports the project within its 7th Framework Programme (FP7) with 3.7 million Euro funding for three years.
Current problems of photocatalysis
People from many countries of the world extensively use pesticides which contaminate drinking and irrigation water with toxic organic compounds. In rural areas of Vietnam, herbicides and dioxins, resistant to degradation, made their way into the water cycle during the Vietnam war. Cancer and abnormalities in newborns can be the consequence. "Photocatalysis is potentially one of the cheapest and most efficient methods for purifying water from pollutants," Radim Bernek says. Sunlight and oxygen establish oxidizing conditions under which toxins are easily degraded into non-harmful substances like water and carbon dioxide. Up to now the process, however, faces two problems: degradation rates are too low and assembly of the needed photoreactors is too expensive.
The aim: cheeper and more efficient catalysts
Within the project "4G-PHOTOCAT", the researchers aim to develop cost-efficient photocatalysts with a considerably improved degradation rate. Therefore they fabricate innovative composite materials consisting of semiconductors and nanostructured metal oxides. In order to achieve the optimal architecture for the product, they employ advanced chemical deposition techniques with a high degree of control over composition and morphology. "Our ultimate goal is to implement the newly developed photocatalysts into a liquid paint," Radim Bernek says. "Photoreactors painted with that liquid can be used, for example, for water decontamination in remote rural areas of Vietnam."
Collaborators
"4G-PHOTOCAT "allies the expertise of seven academic and three industrial partners from five European countries and two Southeast Asian countries. At the RUB, Prof. Dr. Radim Bernek collaborates with Prof. Dr. Roland A. Fischer (Inorganic Chemistry II), Prof. Dr. Martin Muhler, and Dr. Jennifer Strunk (Industrial Chemistry). The international collaborators include scientists from the University College London, J. Heyrovsk Institute of Physical Chemistry in Prague, Jagiellonian University Krakow, University of Helsinki, Universiti Teknologi Malaysia, and Hanoi University of Agriculture. Furthermore, industrial partners from Finland (Picosun), Czech Republic (Advanced Materials), and Vietnam (Q&A) have joined the team.
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Figure online
A figure related to this press release can be found online at: http://aktuell.ruhr-uni-bochum.de/pm2013/pm00051.html.de
Further information
Jun.-Prof. Dr. Radim Bernek, Photoactive Materials Group, Faculty of Chemistry and Biochemistry at the Ruhr-Universitt, 44780 Bochum, Germany, Tel. +49/234-32-29431, E-mail: radim.beranek@rub.de
Editorial journalist: Dr. Julia Weiler
[ | E-mail | Share ] ?
AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.
Public release date: 20-Feb-2013[ | E-mail |
Share ] Contact: Jun.-Prof. Dr. Radim Bernek
radim.beranek@rub.de
49-234-322-9431
Ruhr-University Bochum
EU supports project '4G-PHOTOCAT' with 3.7 million Euro funding
Only light, aerial oxygen, and a catalyst are needed to remove pollutants from water. RUB researchers led by Prof. Radim Bernek collaborate with colleagues from seven different countries in order to develop a photocatalyst that is efficient enough to be profitable. For that purpose, they combine sunlight-absorbing semiconductors and nanostructured materials which they optimize for electron transfer processes. The aim is to implement the newly developed photocatalysts into a liquid paint with which photoreactors can easily be coated. The EU supports the project within its 7th Framework Programme (FP7) with 3.7 million Euro funding for three years.
Current problems of photocatalysis
People from many countries of the world extensively use pesticides which contaminate drinking and irrigation water with toxic organic compounds. In rural areas of Vietnam, herbicides and dioxins, resistant to degradation, made their way into the water cycle during the Vietnam war. Cancer and abnormalities in newborns can be the consequence. "Photocatalysis is potentially one of the cheapest and most efficient methods for purifying water from pollutants," Radim Bernek says. Sunlight and oxygen establish oxidizing conditions under which toxins are easily degraded into non-harmful substances like water and carbon dioxide. Up to now the process, however, faces two problems: degradation rates are too low and assembly of the needed photoreactors is too expensive.
The aim: cheeper and more efficient catalysts
Within the project "4G-PHOTOCAT", the researchers aim to develop cost-efficient photocatalysts with a considerably improved degradation rate. Therefore they fabricate innovative composite materials consisting of semiconductors and nanostructured metal oxides. In order to achieve the optimal architecture for the product, they employ advanced chemical deposition techniques with a high degree of control over composition and morphology. "Our ultimate goal is to implement the newly developed photocatalysts into a liquid paint," Radim Bernek says. "Photoreactors painted with that liquid can be used, for example, for water decontamination in remote rural areas of Vietnam."
Collaborators
"4G-PHOTOCAT "allies the expertise of seven academic and three industrial partners from five European countries and two Southeast Asian countries. At the RUB, Prof. Dr. Radim Bernek collaborates with Prof. Dr. Roland A. Fischer (Inorganic Chemistry II), Prof. Dr. Martin Muhler, and Dr. Jennifer Strunk (Industrial Chemistry). The international collaborators include scientists from the University College London, J. Heyrovsk Institute of Physical Chemistry in Prague, Jagiellonian University Krakow, University of Helsinki, Universiti Teknologi Malaysia, and Hanoi University of Agriculture. Furthermore, industrial partners from Finland (Picosun), Czech Republic (Advanced Materials), and Vietnam (Q&A) have joined the team.
###
Figure online
A figure related to this press release can be found online at: http://aktuell.ruhr-uni-bochum.de/pm2013/pm00051.html.de
Further information
Jun.-Prof. Dr. Radim Bernek, Photoactive Materials Group, Faculty of Chemistry and Biochemistry at the Ruhr-Universitt, 44780 Bochum, Germany, Tel. +49/234-32-29431, E-mail: radim.beranek@rub.de
Editorial journalist: Dr. Julia Weiler
[ | E-mail | Share ] ?
AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.
Source: http://www.eurekalert.org/pub_releases/2013-02/rb-pwc022013.php
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