*-algebra

In mathematics, and more specifically in abstract algebra, a *-algebra (or involutive algebra) is a mathematical structure consisting of two involutive rings $R$ and $A$ , where $R$ is commutative and $A$ has the structure of an associative algebra over $R$ . Involutive algebras generalize the idea of a number system equipped with conjugation, for example the complex numbers and complex conjugation, matrices over the complex numbers and conjugate transpose, and linear operators over a Hilbert space and Hermitian adjoints. However, it may happen that an algebra admits no involution at all.

Terminology

*-ring

In mathematics, a *-ring is a ring with a map $* : A \to A$ that is an antiautomorphism and an involution.

More precisely, $*$ is required to satisfy the following properties:^[1]

$(x + y)* = x * + y *$
$(x y)* = y * x *$
$1* = 1$
$(x *)* = x$

for all $x, y$ in $A$ .

This is also called an involutive ring, involutory ring, and ring with involution. Note that the third axiom is actually redundant, because the second and fourth axioms imply $1*$ is also a multiplicative identity, and identities are unique.

Elements such that $x * = x$ are called self-adjoint.^[2]

Archetypical examples of a *-ring are fields of complex numbers and algebraic numbers with complex conjugation as the involution. One can define a sesquilinear form over any *-ring.

Also, one can define *-versions of algebraic objects, such as ideal and subring, with the requirement to be *-invariant: $x \in I \Rightarrow x * \in I$ and so on.

*-algebra

A *-algebra $A$ is a *-ring,^[a] with involution * that is an associative algebra over a commutative *-ring $R$ with involution $'$ , such that $(r x)* = r' x * \forall r \in R, x \in A$ .^[3]

The base *-ring $R$ is usually the complex numbers (with $'$ acting as complex conjugation) and is commutative with $A$ such that $A$ is both left and right algebra.^{[clarification needed]}

Since $R$ is central in $A$ , that is,^{[clarification needed]}

rx = xr \forall r \in R, x \in A

the * on $A$ is conjugate-linear in $R$ , meaning^{[clarification needed]}

(λ x + μ y)* = λ' x * + μ' y *

for $λ, μ \in R, x, y \in A$ .

A *-homomorphism $f : A \to B$ is an algebra homomorphism that is compatible with the involutions of $A$ and $B$ , i.e.,

$f (a *) = f (a)*$ for all $a$ in $A$ .^[2]

Philosophy of the *-operation

The *-operation on a *-ring is analogous to complex conjugation on the complex numbers. The *-operation on a *-algebra is analogous to taking adjoints in $GL n (C)$ .

Notation

The * involution is a unary operation written with a postfixed star glyph centered above or near the mean line:

x \mapsto x *

, or

x \mapsto x *

(TeX: x^*),

but not as " $x *$ "; see the asterisk article for details.

Examples

Any commutative ring becomes a *-ring with the trivial (identical) involution.
The most familiar example of a *-ring and a *-algebra over reals is the field of complex numbers $C$ where * is just complex conjugation.
More generally, a field extension made by adjunction of a square root (such as the imaginary unit √−1) is a *-algebra over the original field, considered as a trivially-*-ring. The * flips the sign of that square root.
A quadratic integer ring (for some $D$ ) is a commutative *-ring with the * defined in the similar way; quadratic fields are *-algebras over appropriate quadratic integer rings.
Quaternions, split-complex numbers, dual numbers, and possibly other hypercomplex number systems form *-rings (with their built-in conjugation operation) and *-algebras over reals (where * is trivial). Note that neither of the three is a complex algebra.
Hurwitz quaternions form a non-commutative *-ring with the quaternion conjugation.
The matrix algebra of $n \times n$ matrices over R with * given by the transposition.
The matrix algebra of $n \times n$ matrices over C with * given by the conjugate transpose.
Its generalization, the Hermitian adjoint in the algebra of bounded linear operators on a Hilbert space also defines a *-algebra.
The polynomial ring $R [x]$ over a commutative trivially-*-ring $R$ is a *-algebra over $R$ with $P *(x) = P (- x)$ .
If (A, +, ×, *) is simultaneously a *-ring, an algebra over a ring R (commutative), and (r x)* = r (x*) ∀r ∈ R, x ∈ A, then A is a *-algebra over R (where * is trivial).
- As a partial case, any *-ring is a *-algebra over integers.
Any commutative *-ring is a *-algebra over itself and, more generally, over any its *-subring.
For a commutative *-ring R, its quotient by any its *-ideal is a *-algebra over R.
- For example, any commutative trivially-*-ring is a *-algebra over its dual numbers ring, a *-ring with non-trivial *, because the quotient by $ε = 0$ makes the original ring.
- The same about a commutative ring $K$ and its polynomial ring $K [x]$ : the quotient by $x = 0$ restores $K$ .
In Hecke algebra, an involution is important to the Kazhdan–Lusztig polynomial.
The endomorphism ring of an elliptic curve becomes a *-algebra over the integers, where the involution is given by taking the dual isogeny. A similar construction works for abelian varieties with a polarization, in which case it is called the Rosati involution (see Milne's lecture notes on abelian varieties).

Involutive Hopf algebras are important examples of *-algebras (with the additional structure of a compatible comultiplication); the most familiar example being:

The group Hopf algebra: a group ring, with involution given by $g \mapsto g -1$ .

Non-Example

Not every algebra admits an involution:

Regard the 2x2 matrices over the complex numbers.
Consider the following subalgebra:

${\mathcal {A}}:=\left\{{\begin{pmatrix}a&b\\0&0\end{pmatrix}}:a,b\in \mathbb {C} \right\}$

Any nontrivial antiautomorphism necessarily has the form:

$\varphi _{z}\left[{\begin{pmatrix}1&0\\0&0\end{pmatrix}}\right]={\begin{pmatrix}1&z\\0&0\end{pmatrix}}\quad \varphi _{z}\left[{\begin{pmatrix}0&1\\0&0\end{pmatrix}}\right]={\begin{pmatrix}0&0\\0&0\end{pmatrix}}$

for any complex number $z\in \mathbb {C}$ .
It follows that any nontrivial antiautomorphism fails to be idempotent:

$\varphi _{z}^{2}\left[{\begin{pmatrix}0&1\\0&0\end{pmatrix}}\right]={\begin{pmatrix}0&0\\0&0\end{pmatrix}}\neq {\begin{pmatrix}0&1\\0&0\end{pmatrix}}$

Concluding that the subalgebra admits no involution.

Additional structures

Many properties of the transpose hold for general *-algebras:

The Hermitian elements form a Jordan algebra;
The skew Hermitian elements form a Lie algebra;
If 2 is invertible in the *-ring, then ⁠1/2⁠ $(1 + *)$ and ⁠1/2⁠ $(1 - *)$ are orthogonal idempotents,^[2] called symmetrizing and anti-symmetrizing, so the algebra decomposes as a direct sum of modules (vector spaces if the *-ring is a field) of symmetric and anti-symmetric (Hermitian and skew Hermitian) elements. These spaces do not, generally, form associative algebras, because the idempotents are operators, not elements of the algebra.

Skew structures

Given a *-ring, there is also the map $-* : x \mapsto - x *$ . It does not define a *-ring structure (unless the characteristic is 2, in which case −* is identical to the original *), as $1 \mapsto -1$ , neither is it antimultiplicative, but it satisfies the other axioms (linear, involution) and hence is quite similar to *-algebra where $x \mapsto x *$ .

Elements fixed by this map (i.e., such that $a = - a *$ ) are called skew Hermitian.

For the complex numbers with complex conjugation, the real numbers are the Hermitian elements, and the imaginary numbers are the skew Hermitian.

Notes

^ Most definitions do not require a *-algebra to have the unity, i.e. a *-algebra is allowed to be a *-rng only.

References

^ Weisstein, Eric W. (2015). "C-Star Algebra". Wolfram MathWorld.
^ ^a ^b ^c Baez, John (2015). "Octonions". Department of Mathematics. University of California, Riverside. Archived from the original on 25 March 2015. Retrieved 27 January 2015. {{cite web}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)
^ star-algebra at the nLab

[3] Most definitions do not require a *-algebra to have the unity, i.e. a *-algebra is allowed to be a *-rng only.

[1] Weisstein, Eric W. (2015). "C-Star Algebra". Wolfram MathWorld.

[:0-2] Baez, John (2015). "Octonions". Department of Mathematics. University of California, Riverside. Archived from the original on 25 March 2015. Retrieved 27 January 2015. {{cite web}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)

[4] star-algebra at the nLab

[1]

[2]

[a]

[3]

Terminology

*-ring

*-algebra

Philosophy of the *-operation

Notation

Examples

Non-Example

Additional structures

Skew structures

See also

Notes

References