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Nitrogen-Rich Molybdenum Nitride Synthesized in a Crucible under Air.

Momoka DemuraMasanori NagaoChul-Ho LeeYosuke GotoYusuke NambuMaxim AvdeevYuji MasubuchiTakato MitsudomeWenhao SunKiyoharu TadanagaAkira Miura
Published in: Inorganic chemistry (2024)
The triple bond in N 2 is significantly stronger than the double bond in O 2 , meaning that synthesizing nitrogen-rich nitrides typically requires activated nitrogen precursors, such as ammonia, plasma-cracked atomic nitrogen, or high-pressure N 2 . Here, we report a synthesis of nitrogen-rich nitrides under ambient pressure and atmosphere. Using Na 2 MoO 4 and dicyandiamide precursors, we synthesized nitrogen-rich γ-Mo 2 N 3 in an alumina crucible under an ambient atmosphere, heated in a box furnace between 500 and 600 °C. Byproducts of this metathesis reaction include volatile gases and solid Na(OCN), which can be washed away with water. X-ray diffraction and neutron diffraction showed Mo 2 N 3 with a rock salt structure having cation vacancies, with no oxygen incorporation, in contrast to the more common nitrogen-poor rock salt Mo 2 N with anion vacancies. Moreover, an increase in temperature to 700 °C resulted in molybdenum oxynitride, Mo 0.84 N 0.72 O 0.27 . This work illustrates the potential for dicyandiamide as an ambient-temperature metathesis precursor for an increased effective nitrogen chemical potential under ambient conditions. The classical experimental setting often used for solid-state oxide synthesis, therefore, has the potential to expand the nitride chemistry.
Keyphrases
  • air pollution
  • particulate matter
  • magnetic resonance
  • solid state
  • magnetic resonance imaging
  • mass spectrometry
  • drinking water
  • electron microscopy
  • dual energy
  • advanced cancer
  • amino acid
  • anaerobic digestion