Mesoporous tertiary oxides via a novel amphiphilic approach | Zendy

Natasha Bennett | Zendy; Annela M. Seddon | Zendy; James E. Hallett | Zendy; W. Kockelmann | Zendy; Valeska P. Ting | Zendy; Sajanikumari Sadasivan | Zendy; Robert P. Tooze | Zendy; Simon R. Hall | Zendy

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Mesoporous tertiary oxides via a novel amphiphilic approach

Author(s) -

Natasha Bennett,

Annela M. Seddon,

James E. Hallett,

W. Kockelmann,

Valeska P. Ting,

Sajanikumari Sadasivan,

Robert P. Tooze,

Simon R. Hall

Publication year - 2015

Publication title -

apl materials

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.571

H-Index - 60

ISSN - 2166-532X

DOI - 10.1063/1.4930808

Subject(s) - materials science , mesoporous material , oxide , dysprosium , phase (matter) , amphiphile , chemical engineering , metal , sol gel , porosity , solvent , pyrochlore , inorganic chemistry , nanotechnology , organic chemistry , catalysis , composite material , copolymer , metallurgy , chemistry , polymer , engineering

We report a facile biomimetic sol-gel synthesis using the sponge phase formed by the lipid monoolein as a structure-directing template, resulting in high phase purity, mesoporous dysprosium- and gadolinium titanates. The stability of monoolein in a 1,4-butanediol and water mixture complements the use of a simple sol-gel metal oxide synthesis route. By judicious control of the lipid/solvent concentration, the sponge phase of monoolein can be directly realised in the pyrochlore material, leading to a porous metal oxide network with an average pore diameter of 10 nm.

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