Cobalt(II) chloride
Overview
Cobalt(II) chloride is the chemical compound with the formula CoCl2, although the term is used also to refer to the hexahydrate, which is a different chemical compound. CoCl2 is blue, and CoCl2·6H2O is deep magenta. Because of this dramatic color change and the ease of the hydration/dehydration reaction, "cobalt chloride" is used as an indicator for water. The magenta hexahydrate is probably the most familiar cobalt compound in the laboratory.
Aqueous solutions of both CoCl2 and the hydrate contain the species trans-[CoCl2(H2O)4]. This is maintained in the solid state by the hexahydrate, the remaining two water molecules in its formula unit being water of crystallization. This species dissolves readily in water and alcohol. It has the interesting property that a concentrated aqueous solution is red at room temperature, but becomes blue when heated.[1] CoCl2·6H2O is deliquescent and the anhydrous salt CoCl2 is hygroscopic, readily converting to the hydrate.
Chemical properties
CoCl2·6H2O and CoCl2 are weak Lewis acids that convert to many other complexes. These cobalt (II) complexes are usually either octahedral or tetrahedral. Examples include:
- CoCl2·6H2O + 4 C5H5N → CoCl2(C5H5N)4 + 6 H2O
- CoCl2·6H2O + 2 P(C6H5)3 → CoCl2{P(C6H5)3}2 + 6 H2O
- CoCl2 + 2 [(C2H5)4N]Cl → [(C2H5)4N)]2[CoCl4][2]
Otherwise, aqueous solutions of cobalt(II) chlorides behave like other cobalt(II) salts, such as precipitating CoS upon treatment with H2S.
Co(III) derivatives
In the presence of ammonia or amines, cobalt(II) is readily oxidised by atmospheric oxygen to give a variety of cobalt(III) complexes. For example:
- 4 CoCl2·6H2O + 4 [NH4]Cl + 20 NH3 + O2 → 4 [Co(NH3)6]Cl3 + 26 H2O
The reaction is often performed in the presence of charcoal as a catalyst, or hydrogen peroxide is employed in place of air. Other highly basic ligands including carbonate, acetylacetonate, and oxalate induce the formation of Co(III) derivatives. Simple carboxylates and halides do not.
Unlike Co(II) complexes, Co(III) complexes are very slow to exchange ligands, so they are said to be kinetically inert. The German chemist Alfred Werner was awarded the Nobel prize in 1913 for his studies on a series of these cobalt(III) compounds, work that led to an understanding of the structures of such coordination compounds.
Instability of CoCl3
The existence of cobalt(III) chloride, CoCl3, is disputed, although it is listed in some compendia.[3] An authoritative monograph[4] states, "Apart from CoF3, the only known halides of cobalt are the dihalides." The reduction potential for Co3+ + e- → Co2+ is more favorable (+1.92 V) than the reduction Cl2 to Cl- (+1.36 V). This analysis suggests also that the naked cation Co3+ would oxidize chloride to chlorine, precluding the formation of CoCl3. Stated differently, CoCl2 is unreactive toward Cl2. This analysis changes considerably in the presence of ligands of Lewis basicity superior to chloride's, such as amines.
Preparation
Cobalt(II) chloride can be prepared in its anhydrous form from cobalt metal and chlorine gas:
The hydrated form can be prepared from cobalt(II) hydroxide or cobalt(II) carbonate and hydrochloric acid.
Uses
A common use for cobalt(II) chloride is for the detection of moisture, for example in drying agents such as silica gel. In the US calcium sulfate is sold as a drying agent under the trade name Drierite. When cobalt(II) chloride is added as an indicator, the drying agent is blue when still active, pink when exhausted, corresponding to the anhydrous and hydrated forms of CoCl2 respectively. Similarly, paper impregnated with cobalt chloride, known as "cobalt chloride paper" is likewise used to detect the presence of water.
In the laboratory, cobalt(II) chloride serves as a standard precursor for the synthesis of other cobalt compounds. For example, the reaction of 1-norbonyllithium with CoCl2 produces a brown, thermally stable cobalt(IV) tetralkyl[5] — the only compound of its kind for which the detailed structure is fully known[4]:
Reaction of anhydrous CoCl2 with sodium cyclopentadienylide in THF gives the black sandwich compound cobaltocene. This 19-electron species is a good reducing agent, being readily oxidised to the yellow 18-electron cobaltacenium cation, which is isoelectronic with ferrocene.
References
- ↑ The Merck Index, 7th edition, Merck & Co, Rahway, New Jersey, USA, 1960.
- ↑ Gill, N. S. and Taylor, F. B., "Tetrahalo Complexes of Dipositive Metals in the First Transition Series", Inorganic Syntheses, 1967, volume 9, pages 136-142.
- ↑ Handbook of Chemistry and Physics, 71st edition, CRC Press, Ann Arbor, Michigan, 1990.
- ↑ 4.0 4.1 Template:Greenwood&Earnshaw
- ↑ Erin K. Byrne, Darrin S. Richeson and Klaus H. Theopold (1986). "Tetrakis(1-norbornyl)cobalt, a low spin tetrahedral complex of a first row transition metal". J. Chem. Soc., Chem. Commun.: 1491–1492. doi:10.1039/C39860001491.
External links
- International Chemical Safety Card 0783
- National Pollutant Inventory - Cobalt fact sheet
- IARC Monograph "Cobalt and Cobalt Compounds"