Sodium cyanide
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Sodium cyanide is a compound with the formula NaCN and the structure Template:Chem2. It is a white, water-soluble solid. Cyanide has a high affinity for metals, which leads to the high toxicity of this salt. Its main application, in gold mining, also exploits its high reactivity toward metals. It is a moderately strong base.
Production and chemical propertiesEdit
Sodium cyanide is produced by treating hydrogen cyanide with sodium hydroxide:<ref name=Ullmann/>
Worldwide production was estimated at 500,000 tons in the year 2006. Formerly it was prepared by the Castner process involving the reaction of sodium amide with carbon at elevated temperatures.
The structure of solid NaCN is related to that of sodium chloride.<ref>Wells, A.F. (1984) Structural Inorganic Chemistry, Oxford: Clarendon Press. Template:ISBN.</ref> The anions and cations are each six-coordinate. Potassium cyanide (KCN) adopts a similar structure.<ref>Template:Cite journal</ref>
When treated with acid, it forms the toxic gas hydrogen cyanide:
Because the salt is derived from a weak acid, sodium cyanide readily reverts to HCN by hydrolysis; the moist solid emits small amounts of hydrogen cyanide, which is thought to smell like bitter almonds (not everyone can smell it—the ability thereof is due to a genetic trait<ref>{{#ifeq:|none||{{#switch: | short = OMIM: | shortlink = OMIM: | plain = Online Mendelian Inheritance in Man: | full | #default = Online Mendelian Inheritance in Man (OMIM):}}}} {{#if: |{{{2}}} - }} 304300</ref>). Sodium cyanide reacts rapidly with strong acids to release hydrogen cyanide. This dangerous process represents a significant risk associated with cyanide salts. It is detoxified most efficiently with hydrogen peroxide (Template:Chem2) to produce sodium cyanate (NaOCN) and water:<ref name="Ullmann" />
ApplicationsEdit
Cyanide miningEdit
Template:Anchor Gold cyanidation (also known as the cyanide process) is the dominant technique for extracting gold, much of which is obtained from low-grade ore. More than 70% of cyanide consumption globally is used for this purpose. The application exploits the high affinity of gold(I) for cyanide, which induces gold metal to oxidize and dissolve in the presence of air (oxygen) and water, producing the salt sodium dicyanoaurate (or sodium gold cyanide) (Template:Chem2):<ref name=Ullmann/>
A similar process uses potassium cyanide (KCN, a close relative of sodium cyanide) to produce potassium dicyanoaurate (Template:Chem2).
These soluble forms of gold (and silver) can be converted back to the metals by electrolysis.
Chemical feedstockEdit
Some commercially significant chemicals are derived from cyanide: cyanuric chloride, cyanogen chloride, and cyanogen.<ref name=Ullmann/>
Several specialty nitriles may be produced by alkylation of cyanide, a strong nucleophile. Illustrative is the synthesis of benzyl cyanide by the reaction of benzyl chloride and sodium cyanide:<ref>Template:Cite journal</ref>
ElectroplatingEdit
Cyanide baths (solutions) of metal ions are used to electroplate many metals, including platinum, gold, and silver. Cadmium plating gives excellent corrosion resistance and is achieved using cadmium oxide and sodium cyanide.<ref>Template:Cite book</ref> Copper 'strikes' (thin high quality layers) are traditionally formed using cyanide electroplating, these thin interstitial layers allow adhesion between metals that are usually incompatible, such as chromium and aluminium.Template:Cn
Niche usesEdit
Being highly toxic, sodium cyanide is used to kill or stun rapidly such as in collecting jars used by entomologists and in widely illegal cyanide fishing.
It was used as an insecticide, rodenticide and antibacterial, but these uses were cancelled by the EPA in 1987.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
ToxicityEdit
{{#invoke:Labelled list hatnote|labelledList|Main article|Main articles|Main page|Main pages}} Sodium cyanide, like other soluble cyanide salts, is among the most rapidly acting of all known poisons. NaCN is a potent inhibitor of respiration, acting on mitochondrial cytochrome oxidase and hence blocking electron transport. This results in decreased oxidative metabolism and oxygen utilization. Lactic acidosis then occurs as a consequence of anaerobic metabolism. An oral dosage as small as 200–300 mg can be fatal.
DisposalEdit
Due to toxicity considerations, the disposal of cyanide is subject to stringent regulations. Industrial cyanide effluent is typically destroyed by oxidation using peroxysulfuric acid, hydrogen peroxide, sulfur dioxide/copper salts ("Inco process") or all three ("Combiox Process"). Use of sodium hypochlorite, traditional for laboratory-scale wastes, is impractical on a commercial scale. Hydrolysis at higher temperatures is highly effective, but requires specialized equipment. Lastly, cyanide wastes can be acidified for recovery of hydrogen cyanide.<ref name=Ullmann>Template:Cite book</ref>
ReferencesEdit
External linksEdit
- Institut national de recherche et de sécurité (INRS), "Cyanure de sodium. Cyanure de potassium", Fiche toxicologique n° 111, Paris, 2006, 6 pp. (PDF file, in French)
- International Chemical Safety Card 1118
- Hydrogen cyanide and cyanides (CICAD 61)
- National Pollutant Inventory - Cyanide compounds fact sheet
- NIOSH Pocket Guide to Chemical Hazards
- Template:EINECSLink
- Template:PubChem
- CSST (Canada)
- Sodium cyanide hazards to fish and other wildlife from gold
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