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Structure–Activity Relationships of Nickel–Hexaaluminates in Reforming Reactions Part I: Controlling Nickel Nanoparticle Growth and Phase Formation
Author(s) -
Roussière Thomas,
Schelkle Korwin M.,
Titlbach Sven,
Wasserschaff Guido,
Milanov Andrian,
Cox Gerhard,
Schwab Ekkehard,
Deutschmann Olaf,
Schulz Linus,
Jentys Andreas,
Lercher Johannes,
Schunk Stephan A.
Publication year - 2014
Publication title -
chemcatchem
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.497
H-Index - 106
eISSN - 1867-3899
pISSN - 1867-3880
DOI - 10.1002/cctc.201300960
Subject(s) - calcination , nickel , nanoparticle , materials science , chemical engineering , phase (matter) , catalysis , inorganic chemistry , chemistry , nanotechnology , metallurgy , organic chemistry , engineering
The controlled synthesis of hexaaluminates ANi y Al 12− y O 19− δ (A=Ba, La, Sr, and y =0.25, 0.5, 1) is reported by a freeze drying route. This route allows the use of moderate temperatures of approximately 1200 °C to obtain hexaaluminates of high phase purity (>80 wt %) as well as high specific surface areas (10–30 m 2 g −1 ). Under reducing conditions at elevated temperatures, nickel expulsion from the hexaaluminate framework can be observed. High stability of the crystalline phase is observed even if all substitution cations leave the hexaaluminate framework. The moderate calcination temperature of 1200 °C facilitates the reducibility of the Ni–hexaaluminates compared to Ni–hexaaluminates calcined at 1600 °C. SEM and TEM imaging revealed that Ni–hexaaluminates with low Ni loading ( y =0.25) and calcined at moderate temperature (1200 °C) lead under reducing atmosphere to the formation of strong textural growth and highly disperse and highly textured Ni 0 nanoparticles. Nanoparticle growth is associated to surface defect sites occurring on the hexaaluminate platelets.