Selenium

Selenium is a chemical element; it has symbol Se and atomic number 34. It has various physical appearances, including a brick-red powder, a vitreous black solid, and a grey metallic-looking form. It seldom occurs in this elemental state or as pure ore compounds in Earth's crust. Selenium was discovered in 1817 by italics=unset, who noted the similarity of the new element to the previously discovered tellurium.
Selenium is found in metal sulfide ores, where it substitutes for sulfur. Commercially, selenium is produced as a byproduct in the refining of these ores. Minerals that are pure selenide or selenate compounds are rare. The chief commercial uses for selenium today are glassmaking and pigments. Selenium is a semiconductor and is used in photocells. Applications in electronics, once important, have been mostly replaced with silicon semiconductor devices. Selenium is still used in a few types of DC power surge protectors and one type of fluorescent quantum dot.
Although trace amounts of selenium are necessary for cellular function in many animals, including humans, both elemental selenium and selenium salts are toxic in even small doses, causing selenosis. Symptoms include : diarrhea, fatigue, hair loss, joint pain, nail brittleness or discoloration, nausea, headache, tingling, vomiting, and fever.
Selenium is listed as an ingredient in many multivitamins and other dietary supplements, as well as in infant formula, and is a component of the antioxidant enzymes glutathione peroxidase and thioredoxin reductase as well as in three deiodinase enzymes. Selenium requirements in plants differ by species, with some plants requiring relatively large amounts and others apparently not requiring any.

Characteristics

Physical properties

Selenium forms several allotropes that interconvert with temperature changes, depending somewhat on the rate of temperature change. When prepared in chemical reactions, selenium is usually an amorphous, brick-red powder. When rapidly melted, it forms the black, vitreous form, usually sold commercially as beads. The structure of black selenium is irregular and complex and consists of polymeric rings with up to 1000 atoms per ring. Black selenium is a brittle, lustrous solid that is slightly soluble in CS₂. Upon heating, it softens at 50 °C and converts to gray selenium at 180 °C; the transformation temperature is reduced by presence of halogens and amines.
The red α, β, and γ forms are produced from solutions of black selenium by varying the evaporation rate of the solvent. They all have a relatively low, monoclinic crystal symmetry and contain nearly identical puckered cyclooctaselenium rings as in sulfur. The eight atoms of a ring are not equivalent, and in fact in the γ-monoclinic form, half the rings are in one configuration and half in another. The packing is most dense in the α form. In the Se₈ rings, the Se–Se distance varies depending on where the pair of atoms is in the ring, but the average is 233.5 pm, and the Se–Se–Se angle is on average 105.7°. Other selenium allotropes may contain Se₆ or Se₇ rings.
The most stable and dense form of selenium is gray and has a chiral hexagonal crystal lattice consisting of helical polymeric chains, where the Se–Se distance is 237.3 pm and Se–Se–Se angle is 103.1°. The minimum distance between chains is 343.6 pm. Gray selenium is formed by mild heating of other allotropes, by slow cooling of molten selenium, or by condensing selenium vapor just below the melting point. Whereas other selenium forms are insulators, gray selenium is a semiconductor showing appreciable photoconductivity. Unlike the other allotropes, it is insoluble in CS₂. It resists oxidation by air and is not attacked by nonoxidizing acids. With strong reducing agents, it forms polyselenides. Selenium does not exhibit the changes in viscosity that sulfur undergoes when gradually heated.

Isotopes

Selenium has seven naturally occurring isotopes. Five of these, ⁷⁴Se, ⁷⁶Se, ⁷⁷Se, ⁷⁸Se, ⁸⁰Se, are stable, with ⁸⁰Se being the most abundant. Also naturally occurring is the long-lived primordial radionuclide ⁸²Se, with a half-life of 8.76×10¹⁹ years. The non-primordial radioisotope ⁷⁹Se also occurs in minute quantities in uranium ores as a product of nuclear fission. Selenium also has numerous unstable synthetic isotopes ranging from ⁶⁴Se to ⁹⁵Se; the most stable are ⁷⁵Se with a half-life of 119.78 days and ⁷²Se with a half-life of 8.4 days. Isotopes lighter than the stable isotopes primarily undergo beta plus decay to isotopes of arsenic, and isotopes heavier than the stable isotopes undergo beta minus decay to isotopes of bromine, with some minor neutron emission branches in the heaviest known isotopes.

Isotope	Nature	Origin	Half-life
⁷⁴Se	Primordial		Stable
⁷⁶Se	Primordial		Stable
⁷⁷Se	Primordial	Fission product	Stable
⁷⁸Se	Primordial	Fission product	Stable
⁷⁹Se	Trace	Fission product	yr
⁸⁰Se	Primordial	Fission product	Stable
⁸²Se	Primordial	Fission product*	8.76 yr

Chemical compounds

Selenium compounds commonly exist in the oxidation states −2, +2, +4, and +6. It is a nonmetal with properties that are intermediate between the elements above and below in the periodic table, sulfur and tellurium, and also has similarities to arsenic.

Chalcogen compounds

Selenium forms two oxides: selenium dioxide and selenium trioxide. Selenium dioxide is formed by combustion of elemental selenium:
It is a polymeric solid that forms monomeric SeO₂ molecules in the gas phase. It dissolves in water to form selenous acid, H₂SeO₃. Selenous acid can also be made directly by oxidizing elemental selenium with nitric acid:
Unlike sulfur, which forms a stable trioxide, selenium trioxide is thermodynamically unstable and decomposes to the dioxide above 185 °C:
Selenium trioxide is produced in the laboratory by the reaction of anhydrous potassium selenate and sulfur trioxide.
Salts of selenous acid are called selenites. These include silver selenite and sodium selenite.
Hydrogen sulfide reacts with aqueous selenous acid to produce selenium disulfide:
Selenium disulfide consists of 8-membered rings. It has an approximate composition of SeS₂, with individual rings varying in composition, such as Se₄S₄ and Se₂S₆. Selenium disulfide has been used in shampoo as an antidandruff agent, an inhibitor in polymer chemistry, a glass dye, and a reducing agent in fireworks.
Selenium trioxide may be synthesized by dehydrating selenic acid, H₂SeO₄, which is itself produced by the oxidation of selenium dioxide with hydrogen peroxide:

Halogen compounds

Selenium reacts with fluorine to form selenium hexafluoride:
In comparison with its sulfur counterpart, selenium hexafluoride is more reactive and is a toxic pulmonary irritant. Selenium tetrafluoride is a laboratory-scale fluorinating agent.
The only stable chlorides are selenium tetrachloride and selenium monochloride, which might be better known as selenium chloride and is structurally analogous to disulfur dichloride. Metastable solutions of selenium dichloride can be prepared from sulfuryl chloride and selenium, and constitute an important reagent in the preparation of selenium compounds. The corresponding bromides are all known, and recapitulate the same stability and structure as the chlorides.
The iodides of selenium are not well known, and for a long time were believed not to exist. There is limited spectroscopic evidence that the lower iodides may form in bi-elemental solutions with nonpolar solvents, such as carbon disulfide and carbon tetrachloride; but even these appear to decompose under illumination.
Some selenium oxyhalides—seleninyl fluoride and selenium oxychloride —have been used as specialty solvents.

Metal selenides

Analogous to the behavior of other chalcogens, selenium forms hydrogen selenide, H₂Se. It is a strongly odiferous, toxic, and colorless gas. It is more acidic than H₂S. In solution it ionizes to HSe⁻. The selenide dianion Se²⁻ forms a variety of compounds, including the minerals from which selenium is obtained commercially. Illustrative selenides include mercury selenide, lead selenide, zinc selenide, and copper indium gallium diselenide. These materials are semiconductors. With highly electropositive metals, such as aluminium, these selenides are prone to hydrolysis, which may be described by this idealized equation:
Alkali metal selenides react with selenium to form polyselenides,, which exist as chains and rings.

Other compounds

Tetraselenium tetranitride, Se₄N₄, is an explosive orange compound analogous to tetrasulfur tetranitride. It can be synthesized by the reaction of selenium tetrachloride with Metal bisamides|.
Selenium reacts with cyanides to yield selenocyanates:

Organoselenium compounds

Selenium, especially in the II oxidation state, forms a variety of organic derivatives. They are structurally analogous to the corresponding organosulfur compounds. Especially common are selenides, diselenides, and selenols. Representatives of selenides, diselenides, and selenols include respectively selenomethionine, diphenyldiselenide, and benzeneselenol. The sulfoxide in sulfur chemistry is represented in selenium chemistry by the selenoxides, which are intermediates in organic synthesis, as illustrated by the selenoxide elimination reaction. Consistent with trends indicated by the double bond rule, selenoketones, RR, and selenaldehydes, RH, are rarely observed.