Formula Zr(NO3)4 Appearance transparent plates | Molar mass 339.2436 g/mol | |
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Zirconium nitrate is a volatile anhydrous transition metal nitrate of zirconium with formula Zr(NO3)4. It has alternate names of zirconium tetranitrate, or zirconium(IV) nitrate.
Contents
It has a UN number of UN 2728 and is class 5.1, meaning oxidising substance.
Formation
Anhydrous Zirconium nitrate can be made from zirconium tetrachloride reacting with dinitrogen pentoxide.
ZrCl4 + 4 N2O5 → Zr(NO3)4 + 4ClNO2
The product can be purified by sublimation in a vacuum. A contaminating substance in this is nitronium pentanitratozirconate. (NO2)Zr(NO3)5.
Zirconium nitrate pentahydrate Zr(NO3)4.5H2O can be formed by dissolving zirconium dioxide in nitric acid and then evaporating the solution until it is dry. However it is easier to crystallise zirconyl nitrate trihydrate ZrO(NO3)2.3H2O from such a solution.
Zirconium is highly resistant to nitric acid even in the presence of other impurities and high temperatures. So zirconium nitrate is not made by dissolving zirconium metal in nitric acid.
Properties
Zirconium nitrate pentahydrate dissolves easily in water and alcohol. In water it is acidic. The pentahydrate crystals have a refractive index of 1.6.
Reactions
In water solution a base such as ammonium hydroxide will cause zirconium hydroxide to precipitate.
Zirconium nitrate can be used as a Lewis acid catalyst in the formation of N-substituted pyrroles.
A mixed aqueous solution of hafnium nitrate and zirconium nitrate can be separated by partitioning the zirconium into tributylphosphate dissolved in kerosene. Zirconium free from hafnium is required for nuclear reactor construction.
Anhydrous zirconium nitrate can nitrate some organic aromatic compounds in an unusual way. Quinoline is nitrated to 3-nitroquinoline and 7-nitroquinoline. Pyridine is nitrated to 3-nitropyridine and 4-nitropyridine.
Related substances
Related substances are zirconium nitrate complexes. Zr(NO3)3.3H2O+ has a tricapped trigonal pyramid, with the nitrates connected by two oxygen atoms each (bidentate). The pentanitrato complex Zr(NO3)5− has all the nitrate groups bidentate, and has a bicapped square antiprism shape.
NO2[Zr(NO3)3.3H2O]2(NO3)3 crystallizes in the hexagonal system, space group P3C1 with unit cell dimensions a=10.292Å b=10.292Å c=14.84Å volume 1632.2Å3 with 2 formulae per cell, density=2.181.
CsZr(NO3)5 crystallizes in the monoclinic system, space group P21/n with unit cell dimensions a=7.497 Å b=11.567 Å c=14.411 Å β=96.01° volume 1242.8Å3 with 4 formulae per cell, density=2.855.
(NH4)Zr(NO3)5.HNO3 crystallizes in the orthorhombic system, space group Pna21 with unit cell dimensions a=14.852 Å b=7.222 Å c=13.177 Å β=90° volume 1413.6 Å3 with 4 formulae per cell, density=2.267.
A mixed nitronium, nitrosonium pentanitratozirconate crystallizing in the tetragonal system also exists.
Use
Zirconium nitrate is manufactured by a number of chemical suppliers. It is used as a source of zirconium for other salts, as an analytical standard, or as a preservative. Zirconium nitrate and nitronium pentanitratozirconate can be used as chemical vapour deposition precursors as they are volatile, and decompose above 100 °C to form zirconia. At 95°C zirconium nitrate sublimes with a pressure of 0.2 mm of Hg and can be deposited as zirconium dioxide on silicon at 285°C. It has the advantage in that it is a single source, meaning it does not have to be mixed with other materials like oxygen, and decomposes at a relatively low temperature, and does not contaminate the surface with other elements such as hydrogen or fluorine.