Scandium(III) oxide or scandia is an inorganic compound with formula Sc<sub>2</sub>O<sub>3</sub>. It is one of several oxides of rare earth elements with a high melting point. It is used in the preparation of other scandium compounds as well as in high-temperature systems (for its resistance to heat and thermal shock), electronic ceramics, and glass composition (as a helper material).
Scandium(III) oxide adopts a cubic crystal structure (point group: tetrahedral (T<sub>h</sub>), space group: Ia) containing 6-coordinate metal centres. Powder diffraction analysis shows Sc−O bond distances of 2.159–2.071 ÃÂ .
Scandium oxide is an insulator with a band gap of 6.0 eV.
Scandium oxide is the primary form of refined scandium produced by the mining industry. Scandium-rich ores, such as thortveitite (Sc,Y)<sub>2</sub>(Si<sub>2</sub>O<sub>7</sub>) and kolbeckite ScPO<sub>4</sub>÷2H<sub>2</sub>O are rare, however trace amounts of scandium are present in many other minerals. Scandium oxide is therefore predominantly produced as a by-product from the extraction of other elements.
Scandium oxide is the primary form of refined scandium produced by the mining industry, making it the start point for all scandium chemistry.
Scandium oxide reacts with most acids upon heating, to produce the expected hydrated product. For example, heating in excess aqueous HCl produces hydrated ScCl<sub>3</sub>÷nH<sub>2</sub>O. This can be rendered anhydrous by evaporation to dryness in the presence of NH<sub>4</sub>Cl, with the mixture then being purified by removal of NH<sub>4</sub>Cl by sublimation at 300-500 ðC. The presence of NH<sub>4</sub>Cl is required, as the hydrated ScCl<sub>3</sub>÷nH<sub>2</sub>O would otherwise form a mixed oxychloride upon drying.
Likewise, it is converted into hydrated scandium(III) triflate (Sc(OTf)<sub>3</sub>÷nH<sub>2</sub>O) by a reaction with triflic acid.
Metallic scandium is produced industrially by the reduction of scandium oxide; this proceeds via conversion to scandium fluoride followed by a reduction with metallic calcium. This process is in some ways similar to the Kroll process for the production of metallic titanium.
Scandium oxide forms scandate salts with alkalis, unlike its higher homologues yttrium oxide and lanthanum oxide (but like lutetium oxide), for example forming K<sub>3</sub>Sc(OH)<sub>6</sub> with KOH. In this, scandium oxide shows more similarity with aluminium oxide.
Natural scandia, although impure, occurs as mineral kangite.