Zinc nitride explained

Zinc nitride (Zn₃N₂) is an inorganic compound of zinc and nitrogen, usually obtained as (blue)grey crystals. It is a semiconductor. In pure form, it has the anti-bixbyite structure.

Chemical properties

Zinc nitride can be obtained by thermally decomposing zincamide (zinc diamine)^[1] in an anaerobic environment, at temperatures in excess of 200 °C. The by-product of the reaction is ammonia.^[2]

3 Zn(NH₂)₂ → Zn₃N₂ + 4 NH₃

It can also be formed by heating zinc to 600 °C in a current of ammonia; the by-product is hydrogen gas.^{[1] [3]}

3 Zn + 2 NH₃ → Zn₃N₂ + 3 H₂

The decomposition of Zinc Nitride into the elements at the same temperature is a competing reaction. At 700 °C Zinc Nitride decomposes. It has also been made by producing an electric discharge between zinc electrodes in a nitrogen atmosphere. Thin films have been produced by chemical vapour deposition of Bis(bis(trimethylsilyl)amido]zinc with ammonia gas onto silica or ZnO coated alumina at 275 to 410 °C.

The crystal structure is anti-isomorphous with Manganese(III) oxide. (bixbyite).^[4] The heat of formation is c. per mol. It is a semiconductor with a reported bandgap of c. 3.2eV, however, a thin zinc nitride film prepared by electrolysis of molten salt mixture containing Li₃N with a zinc electrode showed a band-gap of 1.01 eV.

Zinc nitride reacts violently with water to form ammonia and zinc oxide.^{[1] [2]}

Zn₃N₂ + 3 H₂O → 3 ZnO + 2 NH₃

Zinc nitride reacts with lithium (produced in an electrochemical cell) by insertion. The initial reaction is the irreversible conversion into LiZn in a matrix of beta-Li₃N. These products then can be converted reversibly and electrochemically into LiZnN and metallic Zn.^[5]

See also

• Nitride
• Zinc nitrate

Further reading

• Futsuhara, M. . Yoshioka, K. . Takai, O. . 1998 . Structural, electrical and optical properties of zinc nitride thin films prepared by reactive RF magnetron sputtering . Thin Solid Films . 322 . 1 . 274–281 . 10.1016/S0040-6090(97)00910-3 . 1998TSF...322..274F .
• Lyutaya, M. D. . Bakuta, S. A. . 1980 . Synthesis of the nitrides of Group II elements . Powder Metallurgy and Metal Ceramics . 19 . 2 . 118–122 . 10.1007/BF00792038 . 93036462 .
• Wu, P. . Tiedje, T. . 2016 . Molecular beam epitaxy growth and optical properties of single crystal Zn3N2 films . . 31 . 10 . 1–4 . 10.1088/0268-1242/31/10/10LT01 . 2016SeScT..31jLT01W . 99713171 .

External links

• Material Safety Data Sheet from GFS Chemicals

Notes and References

1. Book: Henry Enfield Roscoe . Roscoe, H. E. . Carl Schorlemmer . Schorlemmer, C. . 1878 . A Treatise on Chemistry: Volume II, The Metals . 2007-11-01 . 4th . 1907 . . London . 650–651 .
2. Book: Bloxam, C. L. . Chemistry, Inorganic and Organic . 2007-10-31 . 9th . 1903 . P. Blakiston's Son & Co. . Philadelphia . 380 .
3. Book: Lowry, M. T. . Thomas Martin Lowry . Inorganic Chemistry . 2007-11-01 . 1922 . . 872 .
4. Partin. D. E.. Williams. D. J.. O'Keeffe. M. . 1997 . The Crystal Structures of Mg₃N₂ and Zn₃N₂ . Journal of Solid State Chemistry . 132 . 1 . 56–59 . 10.1006/jssc.1997.7407 . 1997JSSCh.132...56P .
5. Book: Amatucci, G. G. . Pereira, N. . Nazri, G.-A. . Pistoia, G. . Lithium Batteries: Science and Technology . https://books.google.com/books?id=k4duxuea3eIC&pg=PA256 . 2007-11-01 . 2004 . . 978-1-4020-7628-2 . Nitride and Silicide Negative Electrodes . 256 .