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@ARTICLE{Lerch:9107,
      author       = {Lerch, M. and Janek, J. and Becker, K.D. and Berendts, S.
                      and Boysen, H. and Bredow, T. and Dronskowski, R. and
                      Egginghaus, S.G. and Kilo, M. and Lumey, M.W. and Martin, M.
                      and Reimann, C. and Schweda, E. and Valov, I. and
                      Wiemhöfer, H.D.},
      title        = {{O}xide nitrides: {F}rom oxides to solids with mobile
                      nitrogen ions},
      journal      = {Progress in solid state chemistry},
      volume       = {37},
      issn         = {0079-6786},
      address      = {Oxford [u.a.]},
      publisher    = {Pergamon Press},
      reportid     = {PreJuSER-9107},
      year         = {2009},
      note         = {This work has been funded by the DFG in the frame of the
                      priority program 1136 'Substitutional effects in ionic
                      solids'.},
      abstract     = {The possibility of fast nitrogen ion conduction in solids
                      is reviewed. Promising electrolytes based on three different
                      base compounds are in the focus of this contribution:
                      Zirconium oxide nitrides, tantalum oxide nitrides and
                      mayenite-based materials. All aspects ranging from
                      preparation methods, crystal structures (ideal and defect
                      structure, also at elevated temperatures), transport
                      properties (ionic and electronic conductivity, transference
                      numbers, diffusion) and correlations between structure and
                      physical properties are presented and discussed, in part
                      also in relation to theoretical calculations. Fluorite-type
                      quaternary oxide nitrides of zirconium are proven to be the
                      first known materials with high nitrogen ion mobility. They
                      can be described as fast mixed oxygen/nitrogen conductors
                      but are limited due to the low maximum nitrogen/oxygen ratio
                      achievable. Corresponding phases based on stabilized
                      tantalum oxide nitrides have a superior N/O ratio but show
                      poor thermal stability. For the development of a pure
                      nitrogen ion conductor a different approach has also been
                      investigated: Some cage compounds, in particular mayenite,
                      allow the substitution of oxygen anions not tightly bound in
                      the framework by nitrogen ions. Some of the obtained
                      N-containing phases exhibit an outstanding electrical
                      conductivity at low temperatures. Possible devices and
                      applications such as a new type of a nitrogen sensor and an
                      ammonia-producing fuel cell are introduced and discussed.
                      (C) 2009 Elsevier Ltd. All rights reserved.},
      keywords     = {J (WoSType)},
      cin          = {IFF-6 / JARA-FIT},
      ddc          = {540},
      cid          = {I:(DE-Juel1)VDB786 / $I:(DE-82)080009_20140620$},
      pnm          = {Grundlagen für zukünftige Informationstechnologien},
      pid          = {G:(DE-Juel1)FUEK412},
      shelfmark    = {Chemistry, Inorganic $\&$ Nuclear},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:000273097800004},
      doi          = {10.1016/j.progsolidstchem.2009.11.004},
      url          = {https://juser.fz-juelich.de/record/9107},
}