Molybdenum trioxide explained

Molybdenum trioxide describes a family of inorganic compounds with the formula MoO3(H2O)n where n = 0, 1, 2. The anhydrous compound is produced on the largest scale of any molybdenum compound since it is the main intermediate produced when molybdenum ores are purified. The anhydrous oxide is a precursor to molybdenum metal, an important alloying agent. It is also an important industrial catalyst. It is a yellow solid, although impure samples can appear blue or green.

Molybdenum trioxide occurs as the rare mineral molybdite.

Structure

In the gas phase, three oxygen atoms are bonded to the central molybdenum atom. In the solid state, anhydrous MoO3 is composed of layers of distorted MoO6 octahedra in an orthorhombic crystal. The octahedra share edges and form chains which are cross-linked by oxygen atoms to form layers. The octahedra have one short molybdenum-oxygen bond to a non-bridging oxygen.[1] [2] Also known is a metastable (β) form of MoO3 with a WO3-like structure.[3]

Preparation and principal reactions

MoO3 is produced industrially by roasting the mineral molybdenite (molybdenum disulfide), the chief ore of molybdenum:

Similar procedures apply to the recovery of molybdenum from spent catalysts. The resulting trioxide can be purified by sublimation.The laboratory synthesis of the dihydrate entails acidification of aqueous solutions of sodium molybdate with perchloric acid:[4]

The dihydrate loses water readily to give the monohydrate. Both are bright yellow in color. Molybdenum trioxide dissolves slightly in water to give "molybdic acid". In base, it dissolves to afford the molybdate anion.

Uses

Molybdenum trioxide is used to manufacture molybdenum metal:

MoO3 + 3 H2 → Mo + 3 H2OMolybdenum trioxide is also a component of the co-catalyst used in the industrial production of acrylonitrile by the oxidation of propene and ammonia.

Because of its layered structure and the ease of the Mo(VI)/Mo(V) coupling, MoO3 is of interest in electrochemical devices and displays. It has been described as "the most commonly used TMO [transition metal oxide] in organic electronics applications ... it is evaporated at relatively low temperature (~400 °C)."[5] It has favourable electronic and chemical properties for use as interfacing layers, p-type dopants and hole transport materials in OLEDs, organic solar cells and perovskite solar cells,[6] especially when forming an ohmic contact to organic semiconductors.[7]

Cited sources

External links

Notes and References

  1. Web site: Molybdite Mineral Data. Webmineral.
  2. Wells, A.F. (1984) Structural Inorganic Chemistry, Oxford: Clarendon Press. .
  3. McCarron. E. M.. 1986. β-MoO3: A Metastable Analogue of WO3. J. Chem. Soc., Chem. Commun.. 4. 336–338. 10.1039/C39860000336.
  4. Book: 10.1002/9780470132555.ch56. Heynes, J. B. B. . Cruywagen, J. J. . Inorganic Syntheses . Yellow Molybdenum(VI) Oxide Dihydrate . 1986. 24. 191–2. 9780470132555 .
  5. 10.1002/adma.201201630. Transition Metal Oxides for Organic Electronics: Energetics, Device Physics and Applications . 2012 . Meyer . Jens . Hamwi . Sami . Kröger . Michael . Kowalsky . Wolfgang . Riedl . Thomas . Kahn . Antoine . Advanced Materials . 24 . 40 . 5408–5427 . 22945550 . 2012AdM....24.5408M . 197055498 .
  6. White . Robin T. . Thibau . Emmanuel S. . Lu . Zheng-Hong . 2016-02-16 . Interface Structure of MoO3 on Organic Semiconductors . Scientific Reports . en . 6 . 1 . 21109 . 10.1038/srep21109 . 2045-2322 . 4754744 . 26880185. 2016NatSR...621109W .
  7. Gong . Yongshuai . Dong . Yiman . Zhao . Biao . Yu . Runnan . Hu . Siqian . Tan . Zhan'ao . 2020 . Diverse applications of MoO 3 for high performance organic photovoltaics: fundamentals, processes and optimization strategies . Journal of Materials Chemistry A . en . 8 . 3 . 978–1009 . 10.1039/C9TA12005J . 213237371 . 2050-7488.