Three‐Dimensional SnO 2  Nanowire Networks for Multifunctional Applications: From High‐Temperature Stretchable Ceramics to Ultraresponsive Sensors | Zendy

Paulowicz Ingo | Zendy; Hrkac Viktor | Zendy; Kaps Sören | Zendy; Cretu Vasilii | Zendy; Lupan Oleg | Zendy; Braniste Tudor | Zendy; Duppel Viola | Zendy; Tiginyanu Ion | Zendy; Kienle Lorenz | Zendy; Adelung Rainer | Zendy; Mishra Yogendra Kumar | Zendy

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Three‐Dimensional SnO 2 Nanowire Networks for Multifunctional Applications: From High‐Temperature Stretchable Ceramics to Ultraresponsive Sensors

Author(s) -

Paulowicz Ingo,

Hrkac Viktor,

Kaps Sören,

Cretu Vasilii,

Lupan Oleg,

Braniste Tudor,

Duppel Viola,

Tiginyanu Ion,

Kienle Lorenz,

Adelung Rainer,

Mishra Yogendra Kumar

Publication year - 2015

Publication title -

advanced electronic materials

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 2.25

H-Index - 56

ISSN - 2199-160X

DOI - 10.1002/aelm.201500081

Subject(s) - nanowire , materials science , ceramic , nanotechnology , service (business) , nanostructure , computer science , composite material , economy , economics

Stretchable ceramic networks built from quasi‐one‐dimensional (Q1D) structures are important candidates for various applications of nanostructures in real‐world technologies. A flame transport synthesis approach is developed that enables versatile synthesis of interconnected SnO 2 nanowire networks. These SnO 2 structures exhibit interesting defects that are very relevant for the oxide material‐engineering community. Devices based on Q1D SnO 2 structure networks show enormous potential for gas/UV sensing.

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