Contents

Idea

A $*$-algebra is an algebra $A$ (associative or non-associative) equipped with an anti-involution, meaning a map $(-)^\ast:A \to A$ such that

• for all elements $a \in A$ and $b \in A$, $(a b)^\ast = b^\ast a^\ast$

• for all elements $a \in A$, $(a^\ast)^\ast = a$

• $1^\ast = 1$

Definition

In more detail, begin with a commutative ring (often a field, but possibly just a rig) $K$ equipped with an involution (a homomorphism whose square is the identity), written $x \mapsto \bar{x}$. (The usual example for $K$ is the field of complex numbers with involution given by complex conjugation, but the concept of $*$-algebra makes sense in more general contexts. (An example is given by any commutative ring $K$ with trivial involution $\bar{x} \coloneqq x$.)

Then a $K$-$*$-algebra (a $*$-algebra over $K$) is a $K$-module $A$ equipped with a $K$-bilinear map $A\times A \to A$, written as multiplication (and often assumed to be associative) and a $K$-antilinear map $A \to A$, written as $x \mapsto x^*$, such that

• $(x^\ast)^\ast = x$ for all $x$ in $A$ (so we have an involution on the underlying $K$-module), and

• $(x y)^* = y^* x^*$ for all $x,y$ in $A$ (so it is an anti-involution on $A$ itself)

• $1^\ast = 1$.

The hypothesis that the anti-involution is $K$-antilinear means that $(r x)^* = \overline{r} x^*$ for all $r$ in $K$ and all $x$ in $A$ (as well as $(x + y)^* = x^* + y^*$).

If a $K$-$*$-algebra $A$ is itself commutative, then it is in particular a commutative ring with involution, and one can consider $A$-$*$-algebras as well. On the other hand, a commutative ring with involution is simply a commutative $*$-algebra over the ring of integers (with trivial involution), and similarly for rigs and natural numbers.

$*$-Rings

A $*$-ring is simply a $*$-algebra over the ring of integers (with trivial involution). Similarly, a $*$-rig is a $*$-algebra over the rig of natural numbers.

Arguably, when we began this article with a commutative ring $K$ equipped with involution, we should have begun it with a ring with anti-involution instead. However, since the ring (or rig) is commutative, there is no difference.

Banach $*$-algebras

When $K$ is the field $\mathbb{C}$ of complex numbers (or the field $\mathbb{R}$ of real numbers, with trivial involution), we can additionally ask that the $*$-algebra be a Banach algebra; then it is a Banach $*$-algebra. Special cases of this are

• $C^*$-algebras (aka $B^*$-algebras)

• and von Neumann algebras (aka $W^*$-algebras)

Arguably, one should require that the map $*$ be an isometry (which follows already if it is required to be short); some authors require this and some don't. However, this is automatic in the case of $C^*$-algebras (and hence also von Neumann algebras).

Examples

General

Involutive Hopf algebras

Generalizations

This concept could be generalized from the category of $R$-modules to any monoidal category:

Let $(C, I, \otimes)$ be a monoidal category and let $(A, e:I \to A, \pi:A \otimes A \to A)$ be a unital algebra object in $C$. Then $A$ is a $*$-algebra object in $C$ if it comes with a morphism $\iota:A \to A$ such that

• $\iota \circ \iota = \mathrm{id}_A$

• $\iota \circ e = e$

• for all morphisms $a:I \to A$ and $b:I \to A$,

In the category of sets, $*$-algebra objects are called anti-involutive unital magmas, and in the category of abelian groups, associative $*$-algebra objects are called *-rings.

Related concepts

• real part, imaginary part

• anti-linear map, anti-dual linear space

• Hermitian form

• state on a star-algebra

• star-representation

References

See also:

• Wikipedia, star-algebra

Discussion for group algebras:

• Antonio Giambruno, Cesar Polcino Milies and Sudarshan K. Sehgal, Star-group identities on units of group algebras: The non-torsion case, Forum Mathematicum Volume 30 Issue 1 (doi:10.1515/forum-2016-0266)

Discussion of the Example of horizontal chord diagrams:

• David Corfield, Hisham Sati, Urs Schreiber: Fundamental weight systems are quantum states (arXiv:2105.02871)