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{{Use American English|date = March 2019}}
{{Short description|Branch of functional analysis}}
In [[functional analysis]], a branch of [[mathematics]], an '''operator algebra''' is an [[algebra over a field|algebra]] of [[continuous function (topology)|continuous]] [[linear operator]]s on a [[topological vector space]], with the multiplication given by the composition of mappings.
The results obtained in the study of operator algebras are phrased in [[Algebra|algebraic]] terms, while the techniques used are highly analytic.<ref>''Theory of Operator Algebras I'' By Masamichi Takesaki, Springer 2012, p vi</ref> Although the study of operator algebras is usually classified as a branch of functional analysis, it has direct applications to [[representation theory]], [[differential geometry]], [[quantum statistical mechanics]], [[quantum information]], and [[quantum field theory]].
==Overview==
Operator algebras can be used to study
An operator algebra is typically required to be [[closure (mathematics)|closed]] in a specified operator [[topology]] inside the algebra of the whole continuous linear operators. In particular, it is a set of operators with both algebraic and topological closure properties. In some disciplines such properties are [[axiom]]ized and algebras with certain topological structure become the subject of the research.
Though algebras of operators are studied in various contexts (for example, algebras of [[pseudo-differential operator]]s acting on spaces of [[Distribution (mathematics)|distributions]]), the term ''operator algebra'' is usually used in reference to algebras of [[bounded operator]]s on a [[Banach space]] or, even more specially in reference to algebras of operators on a [[Separable space|separable]] [[Hilbert space]], endowed with the operator [[norm (mathematics)|norm]] topology.
In the case of operators on a Hilbert space, the [[Hermitian adjoint]] map on operators gives a natural [[Involution (mathematics)|involution]] which provides an additional algebraic structure which can be imposed on the algebra. In this context, the best studied examples are [[self-adjoint]] operator algebras, meaning that they are closed under taking adjoints. These include [[C*-algebra]]s and [[von Neumann algebra]]s. C*-algebras can be easily characterized abstractly by a condition relating the norm, involution and multiplication. Such abstractly defined C*-algebras can be identified to a certain closed [[Subalgebra#Subalgebras_for_algebras_over_a_ring_or_field|subalgebra]] of the algebra of the continuous linear operators on a suitable Hilbert space. A similar result holds for von Neumann algebras.
Commutative self-adjoint operator algebras can be regarded as the algebra of [[Complex numbers|complex]]
Examples of operator algebras which are not self-adjoint include:
*[[nest algebra]]s
*many [[commutative subspace lattice algebra]]s,
*many [[limit algebra]]s.
==See also==
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