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@ARTICLE{Gonzalez:888067,
      author       = {Gonzalez, Jesus},
      title        = {{P}rocessing of {MAX} phases: {F}rom synthesis to
                      applications},
      journal      = {Journal of the American Ceramic Society},
      volume       = {104},
      number       = {2},
      issn         = {1551-2916},
      address      = {Westerville, Ohio},
      publisher    = {Soc.},
      reportid     = {FZJ-2020-04645},
      pages        = {659–690},
      year         = {2020},
      abstract     = {MAX phases are a large family of materials with more than
                      150 different compositions that have been extensively
                      investigated during the last 25 years. They present a
                      layered structure and a unique combination of properties,
                      bridging the gap between metallic and ceramic properties.
                      However, despite their excellent response of some
                      compositions at high temperature—excellent oxidation
                      resistance up to 1400°C under corrosive environment, good
                      damage and radiation tolerance, thermal shock resistance,
                      and self‐crack healing—their transfer to applications
                      has been limited by three main factors: i) complexity of
                      this large family of materials, ii) unavailability of highly
                      pure commercial powders, and iii) extensive time to license
                      products in strategic fields such as nuclear or aviation. In
                      this article, the main properties and synthesis routes are
                      reviewed, including solid state reaction methods, physical
                      vapor deposition (PVD) techniques and molten salt processes.
                      Emphasis is given to processing routes for developing
                      different structures such as dense bulk samples, ceramic
                      matrix composites, foams with different porosity, coatings
                      by PVD and thermal spray technologies, and near net shaping
                      by slip casting, injection molding, and additive
                      manufacturing. Well‐known and novel potential applications
                      are described such as structural materials for high
                      temperature applications, protective coatings and
                      bond‐coats for gas turbines, accident tolerant fuel
                      cladding in nuclear power plants, solar receiver in
                      concentrated solar power systems, electrical contacts,
                      catalyst, and joining material. Finally, high impact
                      investigations and future challenges are listed in order to
                      facilitate the transfer of MAX phases to the market.},
      cin          = {IEK-1},
      ddc          = {660},
      cid          = {I:(DE-Juel1)IEK-1-20101013},
      pnm          = {113 - Methods and Concepts for Material Development
                      (POF3-113)},
      pid          = {G:(DE-HGF)POF3-113},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:000589529600001},
      doi          = {10.1111/jace.17544},
      url          = {https://juser.fz-juelich.de/record/888067},
}