Antiunitary Operator
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In
mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
, an antiunitary transformation, is a bijective antilinear map :U: H_1 \to H_2\, between two complex Hilbert spaces such that :\langle Ux, Uy \rangle = \overline for all x and y in H_1, where the horizontal bar represents the complex conjugate. If additionally one has H_1 = H_2 then U is called an antiunitary operator. Antiunitary operators are important in quantum theory because they are used to represent certain symmetries, such as time reversal. Their fundamental importance in quantum physics is further demonstrated by Wigner's theorem.


Invariance transformations

In
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, ...
, the invariance transformations of complex Hilbert space H leave the absolute value of scalar product invariant: : , \langle Tx, Ty \rangle, = , \langle x, y \rangle, for all x and y in H. Due to Wigner's theorem these transformations can either be
unitary Unitary may refer to: Mathematics * Unitary divisor * Unitary element * Unitary group * Unitary matrix * Unitary morphism * Unitary operator * Unitary transformation * Unitary representation * Unitarity (physics) * ''E''-unitary inverse semigroup ...
or antiunitary.


Geometric Interpretation

Congruences of the plane form two distinct classes. The first conserves the orientation and is generated by translations and rotations. The second does not conserve the orientation and is obtained from the first class by applying a reflection. On the complex plane these two classes correspond (up to translation) to unitaries and antiunitaries, respectively.


Properties

* \langle Ux, Uy \rangle = \overline = \langle y, x \rangle holds for all elements x, y of the Hilbert space and an antiunitary U . * When U is antiunitary then U^2 is unitary. This follows from \left\langle U^2 x, U^2 y \right\rangle = \overline = \langle x, y \rangle . * For unitary operator V the operator VK , where K is complex conjugate operator, is antiunitary. The reverse is also true, for antiunitary U the operator UK is unitary. * For antiunitary U the definition of the adjoint operator U^* is changed to compensate the complex conjugation, becoming \langle U x,y\rangle = \overline. * The adjoint of an antiunitary U is also antiunitary and U U^* = U^* U = 1. (This is not to be confused with the definition of
unitary operators In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product. Unitary operators are usually taken as operating ''on'' a Hilbert space, but the same notion serves to define the con ...
, as the antiunitary operator U is not complex linear.)


Examples

* The complex conjugate operator K, K z = \overline, is an antiunitary operator on the complex plane. * The operator U = i \sigma_y K = \begin 0 & 1 \\ -1 & 0 \end K, where \sigma_y is the second
Pauli matrix In mathematical physics and mathematics, the Pauli matrices are a set of three complex matrices which are Hermitian, involutory and unitary. Usually indicated by the Greek letter sigma (), they are occasionally denoted by tau () when used in c ...
and K is the complex conjugate operator, is antiunitary. It satisfies U^2 = -1 .


Decomposition of an antiunitary operator into a direct sum of elementary Wigner antiunitaries

An antiunitary operator on a finite-dimensional space may be decomposed as a direct sum of elementary Wigner antiunitaries W_\theta, 0 \le \theta \le \pi. The operator W_0:\Complex \to \Complex is just simple complex conjugation on \mathbb :W_0(z) = \overline For 0 < \theta \le \pi, the operator W_\theta acts on two-dimensional complex Hilbert space. It is defined by :W_\theta\left(\left(z_1, z_2\right)\right) = \left(e^ \overline,\; e^\overline\right). Note that for 0 < \theta \le \pi :W_\theta\left(W_\theta\left(\left(z_1, z_2\right)\right)\right) = \left(e^z_1, e^z_2\right), so such W_\theta may not be further decomposed into {{nowrap, W_0's, which square to the identity map. Note that the above decomposition of antiunitary operators contrasts with the spectral decomposition of unitary operators. In particular, a unitary operator on a complex Hilbert space may be decomposed into a direct sum of unitaries acting on 1-dimensional complex spaces (eigenspaces), but an antiunitary operator may only be decomposed into a direct sum of elementary operators on 1- and 2-dimensional complex spaces.


References

*Wigner, E. "Normal Form of Antiunitary Operators", Journal of Mathematical Physics Vol 1, no 5, 1960, pp. 409–412 *Wigner, E. "Phenomenological Distinction between Unitary and Antiunitary Symmetry Operators", Journal of Mathematical Physics Vol1, no5, 1960, pp.414–416


See also

*
Unitary operator In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product. Unitary operators are usually taken as operating ''on'' a Hilbert space, but the same notion serves to define the con ...
* Wigner's Theorem *
Particle physics and representation theory There is a natural connection between particle physics and representation theory, as first noted in the 1930s by Eugene Wigner. It links the properties of elementary particles to the structure of Lie groups and Lie algebras. According to this con ...
Linear algebra Functional analysis