Cobalt was discovered by George Brandt in 1737. Cobalt exists in valence states from 0 to 5, with the most stable (+2 and +3) being the most common. Although there is only one stable isotope of cobalt, there are a number of unstable isotopes. Two of these, cobalt-60 and cobalt-57, are in use commercially. Cobalt-60 is used for cancer treatment and food irradiation. Cobalt-57 has research applications.

Uses

Cobalt is a relatively rare metal produced primarily as a byproduct of the mining of other metals, chiefly copper. It is the essential trace element found in cyanocobalamin (vitamin B12). This vitamin protects against pernicious anemia and is required in the production of red blood cells. Medicinally, cobalt salts have been used to stimulate the formation of red blood cells in individuals suffering from anemia.

Commercially, cobalt is used primarily in high temperature alloys, tungsten carbide tools, and (with iron and nickel) permanent magnets. Cobalt salts are used in pigments and paint dryers and as catalysts in the petroleum industry.

Environmental Fate

The sources of cobalt in the environment are both natural and synthetic (anthropogenic). Natural sources include soil, seawater spray, volcanic eruptions, and forest fires. Anthropogenic sources include combustion of fossil fuels, metal smelting, sewage sludge, and processing of cobalt alloys. Cobalt is found in the atmosphere in particulate form and returns to the Earth’s surface through dry deposition and with rain or snow. Once in surface water, cobalt generally moves into sediment. Cobalt does not appear to biomagnify significantly in the aquatic food chain. The cobalt that does accumulate in fish is largely found in the nonedible parts of the fish. Seventy-nine percent of the cobalt is transported by rivers globally and precipitates in estuaries.

Under normal environmental conditions, cobalt is expected to bind strongly to soil; thus, migration through soil is very limited. Cobalt in soil can be taken up by plant roots and root vegetables, but does not translocate to the aboveground parts of plants.

Mechanism

Cobalt most often depresses the activity of enzymes, including catalase, amino levulinic acid synthetase, and P-450, enzymes involved in cellular respiration. The Krebs citric acid cycle can be blocked by cobalt resulting in the inhibition of cellular energy production. Cobalt can replace zinc in a number of zincrequired enzymes such as alcohol dehydrogenase. Cobalt can also enhance the kinetics of some enzymes, such as heme oxidase in the liver. Cobalt interferes with and depresses iodine metabolism, resulting in reduced thyroid activity. Reduced thyroid activity can lead to goiter.