Nitric acid

From Sciencemadness Wiki
Revision as of 21:33, 24 August 2015 by Mabus (Talk | contribs)

Jump to: navigation, search
Nitric acid.png

Nitric acid is a strong acid with the formula HNO3. It is a mineral acid, along with hydrochloric, sulfuric, perchloric, and phosphoric acids. It is a powerful oxidizing agent, especially when mixed with sulfuric acid, which produces the nitronium ion in situ.

Properties

Chemical

Nitric acid is an oxidizing acid at room temperature. It is often used in the nitration of organic compounds. It is capable of dissolving metals such as copper and silver due to its oxidizing nature, and will release toxic nitrogen dioxide as an oxidation by product.

Cu + 8 HNO3 → 3 Cu(NO3)2 + 2 NO + 4 H2O

Physical

Concentrated nitric acid is a clear solution with a density of about 1.2 g/ml. When the concentration of the acid surpasses 70%, it becomes classified as fuming nitric acid, this can be identified by visible fuming when air is blown into it. It forms an azeotrope with water at 68% concentration, which makes it difficult to produce the pure substance.

Availability

Nitric acid is available from lab suppliers like Elemental Scientific and Duda Diesel. While the acid itself is not expensive, it requires a mandatory HAZMAT shipping fee of $37.50, making this acid rather expensive for the amateur chemist.

Preparation

Makeshift production of nitric acid by passing nitrogen dioxide gas(right) into chilled hydrogen peroxide(left).

Nitric acid may be prepared by distilling a mixture of a nitrate salt and one equivalent of sulfuric acid at 83ºC. This will produce 70% azeotropic concentrated acid, but the acid will be brown due to dissolved nitrogen dioxide. Dissolved nitrogen dioxide can be oxidized to nitric acid with oxygen or ozone. To produce higher concentrations with dissolved nitrogen oxides, also known as fuming nitric acid, the concentrated acid may be vacuum distilled with additional concentrated sulfuric acid. Hydrochloric acid should never be used, as it reacts with nitric acid to form nitrosyl chloride.

If sulfuric acid of a very high concentration is used in the nitrate salt method, it is possible to distill nitric acid of higher concentration, close to 100%. However, the resulting acid will be fouled by very high concentrations of nitrogen dioxide. This product is known as red fuming nitric acid, or RFNA, and appears like a red-brown liquid that releases brown fumes. RFNA can be converted to a more pure product, white fuming nitric acid, by blowing oxygen through it until the disappearance of the red-brown color. White fuming nitric acid is colorless or yellow and releases white or yellow fumes. It is nitric acid with a concentration of 95 to 99%.

A somewhat less efficient method of producing nitric acid is by the reaction of a mixture containing sulfuric acid and a nitrate salt with copper metal, generating large amounts of nitrogen dioxide gas. The gas may then be bubbled into hydrogen peroxide or water, with hydrogen peroxide producing a higher yield.

Sodium bisulfate can also be use to replace sulfuric acid, however doing so will release nitrogen dioxide rather than nitric acid.

It is possible to produce nitric acid with an Ostwald reactor, or by reacting nitrogen and oxygen in air with an electric spark.

If you need to quickly whip up some dilute nitric acid, you can use the "quick and dirty" method, namely reacting calcium nitrate with sulfuric acid. This method has two downsides: first, even if your reagents are in a perfectly stoichiometric ratio, the resulting acid is still contaminated by a small amount of calcium sulfate that managed to stay in solution. Second, the precipitate of calcium sulfate is incredibly messy and voluminous, the acid looks like sour cream and it is almost impossible to decant it properly. Use this method only if you have a vacuum filtering set. This low-grade acid can be distilled to yield azeotropic nitric acid.

Projects

Nitric acid can be used for many projects including make nitrate salts. When mixed with concentrated sulfuric acid or hydrofluoric acid, nitric acid acts like a base and releases a nitronium ion:

2H2SO4 + HNO3 → NO2+ + 2HSO4- + H2O

This mixture, known as mixed acid can be used for nitrating many organic compounds.

Other:

Handling

Safety

Nitric acid solutions are highly corrosive and will stain the skin yellow as the proteins are nitrated. Care should be taken to not let nitric acid contact the skin. Nitrates should not be used with hydrochloric acid, because this generates nitrosyl chloride.

When handling fuming nitric acid, wear butyl rubber gloves. Other types of rubber may react extremely violently with nitric acid of this concentration. If you don't have butyl rubber, don't wear gloves at all: damage done to your bare hands will be lesser than what rubber on fire can do to you. Nitric acid in general reacts with rubber; do not try to distill it in apparata that contain rubber parts. Use ground glass joints or a retort when distilling nitric acid, especially of fuming concentration.

Storage

Nitric acid is incompatible with most plastics due to its oxidizing nature, though bottle lids made of polypropylene (PP) are acceptable. High concentrations of nitric acid are light sensitive and should be kept in amber glass bottles with ample headroom to prevent pressure build up from nitrogen oxides.

Disposal

Nitric acid can be neutralized with neutralizing compounds, such as carbonates, bicarbonates, oxides, hydroxides. Calcium carbonate is a good neutralizing agent, and, as long as the acid isn't contaminated with heavy metals, the resulting calcium nitrate can be discarded in ground or poured down the drain.

References

Relevant Sciencemadness threads