Simple but Efficient Method for Inhibiting Sintering and Aggregation of Catalytic Pt Nanoclusters on Metal‐Oxide Supports

A simple and efficient method to inhibit aggregation of Pt clusters supported on metal oxide was developed, preserving the accessible clusters surface where catalytically active sites are located even at relatively high temperatures up to 700 K. The key idea was the inclusion of transition metal ato...

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Veröffentlicht in:Chemistry : a European journal 2017-01, Vol.23 (7), p.1531-1538
Hauptverfasser: Koizumi, Kenichi, Nobusada, Katsuyuki, Boero, Mauro
Format: Artikel
Sprache:eng
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Zusammenfassung:A simple and efficient method to inhibit aggregation of Pt clusters supported on metal oxide was developed, preserving the accessible clusters surface where catalytically active sites are located even at relatively high temperatures up to 700 K. The key idea was the inclusion of transition metal atoms such as Ni into the Pt clusters, thus anchoring the clusters through formation of strong chemical bonds with oxygen atoms of the metal‐oxide support. To elucidate the efficiency of the method, first‐principles molecular dynamics enhanced with free‐energy sampling methods were used. These virtual experiments showed how doped Ni atoms, having a stronger affinity to O than Pt, anchor the Pt clusters tightly to the metal‐oxide supports and inhibit their tendency to aggregate on the support. No more sintering: A simple and efficient method to inhibit aggregation of Pt clusters supported on metal oxide is presented and assessed. This method preserves the accessible clusters surface where catalytically active sites are located and is effective even at relatively high temperatures up to 700 K. The key idea is the inclusion of transition metal atoms such as Ni into the Pt clusters, thus anchoring the clusters through formation of strong chemical bonds with oxygen atoms of the metal‐oxide support.
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201604188