marketing seizure: New information on binding gold particles over metal oxide surfaces

New information on binding gold particles over metal oxide surfaces

Public release date: 22-Jan-2013
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Contact: Docent Karoliina Honkala
karoliina.honkala@jyu.fi
358-408-053-686
Academy of Finland

The strong binding of gold on electronically modified calcium oxide can now be understood in detail. In a computational study, researchers Jenni Andersin, Janne Nevalaita, Karoliina Honkala and Hannu Hkkinen at the University of Jyvskyl Nanoscience Center have shown how redox chemistry entirely determines the adsorption strength of gold on the modified oxide where one metal atom is replaced with molybdenum. The study was funded by the Academy of Finland.

The research team applied the so-called Born-Haber cycle to analyse how different terms contribute to adsorption energy. The calculations were done at the supercomputers of the CSC IT Center of Science by employing quantum mechanical simulation methods.

In the oxide lattice, the molybdenum atom donates two electrons into the oxide. When a gold atom adsorbs on the oxide surface, a redox reaction takes place. In this process, a third electron transferred by the dopant is gained by gold, and energy is released. By varying the dopant among several transition metal atoms, the researchers found that the amount of energy released linearly correlates with the ability of the dopant to give an electron. The trend can be used to estimate how much a guest atom stabilises gold adsorption without calculating the adsorption energy.

The research results are important for understanding catalyst-support interaction. The results fully support the experimental observation where gold nanoparticles have been seen to form flat structures over modified calcium oxide surfaces. A similar Born-Haber cycle, as applied in this study, can also be employed to analyse oxide-catalysed chemical reactions that follow the redox mechanism.

Catalysts are commonly used by industry, for instance, in the production of fuels, plastics, fertilisers and other similar products. Metal oxide surfaces are widely used as support materials for metal catalysts particles. The binding properties and shape of metal nanoparticles sensitively depend on the interaction between the support and the catalyst. By tuning this interaction, it is possible to affect the number and properties of catalytically active sites, or even create new sites. One way to modify the interaction is to dope the oxide with guest metal atoms that can donate extra electrons into a material.

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The results of the research team were published in December 2012 in the prestigious chemistry journal Angewandte Chemie: "The Redox Chemistry of Gold with High-Valence Doped Calcium Oxide" (http://onlinelibrary.wiley.com/doi/10.1002/anie.201208443/abstract).
More information:

Docent Karoliina Honkala
University of Jyvskyl, Department of Chemistry, Nanoscience Center
tel. +358 40 805 3686 vfirstname.lastname(at)jyu.fi

Academy of Finland Communications
Communications Specialist Leena Vhkyl
tel. +358 29 533 5139
firstname.lastname(at)aka.fi

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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.

New information on binding gold particles over metal oxide surfaces Public release date: 22-Jan-2013
[ | E-mail | Share ]
Contact: Docent Karoliina Honkala
karoliina.honkala@jyu.fi
358-408-053-686
Academy of Finland

The strong binding of gold on electronically modified calcium oxide can now be understood in detail. In a computational study, researchers Jenni Andersin, Janne Nevalaita, Karoliina Honkala and Hannu Hkkinen at the University of Jyvskyl Nanoscience Center have shown how redox chemistry entirely determines the adsorption strength of gold on the modified oxide where one metal atom is replaced with molybdenum. The study was funded by the Academy of Finland.

The research team applied the so-called Born-Haber cycle to analyse how different terms contribute to adsorption energy. The calculations were done at the supercomputers of the CSC IT Center of Science by employing quantum mechanical simulation methods.

In the oxide lattice, the molybdenum atom donates two electrons into the oxide. When a gold atom adsorbs on the oxide surface, a redox reaction takes place. In this process, a third electron transferred by the dopant is gained by gold, and energy is released. By varying the dopant among several transition metal atoms, the researchers found that the amount of energy released linearly correlates with the ability of the dopant to give an electron. The trend can be used to estimate how much a guest atom stabilises gold adsorption without calculating the adsorption energy.

The research results are important for understanding catalyst-support interaction. The results fully support the experimental observation where gold nanoparticles have been seen to form flat structures over modified calcium oxide surfaces. A similar Born-Haber cycle, as applied in this study, can also be employed to analyse oxide-catalysed chemical reactions that follow the redox mechanism.

Catalysts are commonly used by industry, for instance, in the production of fuels, plastics, fertilisers and other similar products. Metal oxide surfaces are widely used as support materials for metal catalysts particles. The binding properties and shape of metal nanoparticles sensitively depend on the interaction between the support and the catalyst. By tuning this interaction, it is possible to affect the number and properties of catalytically active sites, or even create new sites. One way to modify the interaction is to dope the oxide with guest metal atoms that can donate extra electrons into a material.

###
The results of the research team were published in December 2012 in the prestigious chemistry journal Angewandte Chemie: "The Redox Chemistry of Gold with High-Valence Doped Calcium Oxide" (http://onlinelibrary.wiley.com/doi/10.1002/anie.201208443/abstract).
More information:

Docent Karoliina Honkala
University of Jyvskyl, Department of Chemistry, Nanoscience Center
tel. +358 40 805 3686 vfirstname.lastname(at)jyu.fi

Academy of Finland Communications
Communications Specialist Leena Vhkyl
tel. +358 29 533 5139
firstname.lastname(at)aka.fi

[ | 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/2013-01/aof-nio012213.php
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