Pauli matrices

The Pauli matrices are a set of three 2 × 2 complex matrices which are Hermitian and unitary.[1] Usually indicated by the Greek letter "sigma" (σ), they are occasionally denoted with a "tau" (τ) when used in connection with isospin symmetries. They are:


\sigma_1 = \sigma_x =
\begin{pmatrix}
0&1\\
1&0
\end{pmatrix}

\sigma_2 = \sigma_y =
\begin{pmatrix}
0&-i\\
i&0
\end{pmatrix}

\sigma_3 = \sigma_z =
\begin{pmatrix}
1&0\\
0&-1
\end{pmatrix}

These matrices were used by, then named after, the Austrian-born physicist Wolfgang Pauli (1900–1958), in his study of spin in quantum mechanics.

Each Pauli matrix is Hermitian, and together with the identity I (sometimes considered the zeroth Pauli matrix  \sigma_0 ), the Pauli matrices span the full vector space of 2x2 Hermitian matrices. In the language of quantum mechanics, hermitian matrices are observables, so the Pauli matrices span the space of observables of the 2-dimensional complex Hilbert space. In the context of Pauli's work, \sigma_i is the observable corresponding to spin along the i^{th} coordinate axis in \mathbb{R}^3.

The Pauli matrices (after multiplication by i to make them anti-hermitian), also generate transformations in the sense of Lie algebras: the matrices i\sigma_1,i\sigma_2,i\sigma_3 form a basis for \mathfrak{su}_2, which exponentiates to the spin group SU(2), and for the identical Lie algebra \mathfrak{so_3}, which exponentiates to the Lie group SO(3) of rotations of 3-dimensional space. Moreover, the algebra generated by the four matrices \sigma_0,\sigma_1,\sigma_2,\sigma_3 forms a faithful representation of the 3-dimensional real, Euclidean Clifford Algebra.

Contents

Algebraic properties


\sigma_1^2 = \sigma_2^2 = \sigma_3^2 = -i\sigma_1 \sigma_2 \sigma_3 = \begin{pmatrix} 1&0\\0&1\end{pmatrix} = I

where I is the identity matrix, i.e. the matrices are involutory.

\det (\sigma_i) = -1,
\operatorname{Tr} (\sigma_i) = 0 .

From above we can deduce that the eigenvalues of each σi are ±1.

Eigenvectors and eigenvalues

Each of the (hermitian) Pauli matrices has two eigenvalues, +1 and −1. The corresponding normalized eigenvectors are:


\begin{array}{lclc}
\psi_{x%2B}=\displaystyle\frac{1}{\sqrt{2}}\!\!\!\!\! & \begin{pmatrix}{1}\\{1}\end{pmatrix}, & \psi_{x-}=\displaystyle\frac{1}{\sqrt{2}}\!\!\!\!\! & \begin{pmatrix}{1}\\{-1}\end{pmatrix}, \\
\psi_{y%2B}=\displaystyle\frac{1}{\sqrt{2}}\!\!\!\!\! & \begin{pmatrix}{1}\\{i}\end{pmatrix}, & \psi_{y-}=\displaystyle\frac{1}{\sqrt{2}}\!\!\!\!\! & \begin{pmatrix}{1}\\{-i}\end{pmatrix}, \\
\psi_{z%2B}=                                          & \begin{pmatrix}{1}\\{0}\end{pmatrix}, & \psi_{z-}=                                          & \begin{pmatrix}{0}\\{1}\end{pmatrix}.
\end{array}

Pauli vector

The Pauli vector is defined by

\vec{\sigma} = \sigma_1 \hat{x} %2B \sigma_2 \hat{y} %2B \sigma_3 \hat{z} \,

and provides a mapping mechanism from a vector basis to a Pauli matrix basis as follows


\begin{align}
\vec{a} \cdot \vec{\sigma} &= (a_i \hat{x}_i) \cdot (\sigma_j \hat{x}_j ) \\
&= a_i \sigma_j \hat{x}_i \cdot \hat{x}_j \\
&= a_i \sigma_i
\end{align}

(summation over indices implied). Note that in this vector dotted with Pauli vector operation the Pauli matrices are treated in a scalar like fashion, commuting with the vector basis elements.

Commutation relations

The Pauli matrices obey the following commutation and anticommutation relations:

[\sigma_a, \sigma_b] = 2 i \varepsilon_{a b c}\,\sigma_c,
\{\sigma_a, \sigma_b\} = 2 \delta_{a b} \cdot I.

where \varepsilon_{abc} is the Levi-Civita symbol, \delta_{ab} is the Kronecker delta, and I is the identity matrix.

The above two relations are equivalent to:

\sigma_a \sigma_b = \delta_{ab} \cdot I %2B i \sum_c \varepsilon_{abc} \sigma_c \,.

For example,

\begin{align}
\sigma_1\sigma_2 &= i\sigma_3,\\
\sigma_2\sigma_3 &= i\sigma_1,\\
\sigma_2\sigma_1 &= -i\sigma_3,\\
\sigma_1\sigma_1 &= I.\\
\end{align}

and the summary equation for the commutation relations can be used to prove

(\vec{a} \cdot \vec{\sigma})(\vec{b} \cdot \vec{\sigma}) = (\vec{a} \cdot \vec{b}) \, I %2B i \vec{\sigma} \cdot ( \vec{a} \times \vec{b} ) \quad \quad \quad \quad (1) \,
(as long as the vectors a and b commute with the pauli matrices)

as well as

e^{i (\vec{a} \cdot \vec{\sigma})} = I\cos{a} %2B i (\hat{n} \cdot \vec{\sigma}) \sin{a} \quad \quad \quad \quad \quad \quad (2) \,

for \vec{a} = a \hat{n} .

Completeness relation

An alternative notation that is commonly used for the Pauli matrices is to write the vector index i in the superscript, and the matrix indices as subscripts, so that the element in row \alpha and column \beta of the ith Pauli matrix is \sigma^i_{\alpha\beta}.

In this notation, the completeness relation for the Pauli matrices can be written

\vec{\sigma}\cdot\vec{\sigma}=\sum_{i=1}^3 \sigma^i_{\alpha\beta}\sigma^i_{\gamma\delta} = 2 \delta_{\alpha\delta} \delta_{\beta\gamma} - \delta_{\alpha\beta}\delta_{\gamma\delta}.\,

As noted above, it is common to denote the 2\times2 unit matrix by \sigma_0, so \sigma^0_{\alpha\beta} = \delta_{\alpha\beta}. The completeness relation can therefore alternatively be expressed as

\sum_{i=0}^3 \sigma^i_{\alpha\beta}\sigma^i_{\gamma\delta} = 2 \delta_{\alpha\delta} \delta_{\beta\gamma}\,.

Relation with the permutation operator

Let P_{ij} be the permutation (transposition, actually) between two spins  \sigma_i and  \sigma_j living in the tensor product space  \mathbb{C}^2 \otimes \mathbb{C}^2 ,  P_{ij}|\sigma_i \sigma_j\rangle =  |\sigma_j \sigma_i\rangle . This operator can be written as  P_{ij} = \frac{1}{2}(\vec{\sigma}_i\cdot\vec{\sigma}_j%2B1), as the reader can easily verify.

SU(2)

The matrix group SU(2) is a Lie group, and its Lie algebra is the set of the anti-Hermitian 2×2 matrices with trace 0. Direct calculation shows that the Lie algebra su(2) is the 3 dimensional real algebra spanned by the set {i \sigma_j}. In symbols,

\; \operatorname{su}(2) = \operatorname{span} \{ i \sigma_1, i \sigma_2 , i \sigma_3 \}.

As a result, i \sigma_js can be seen as infinitesimal generators of SU(2).

A Cartan decomposition of SU(2)

This relationship between the Pauli matrices and SU(2) can be explored further, as can be seen from the following simple example. We can write

\; \operatorname{su}(2) =  \operatorname{span} \{i \sigma_2\} \oplus \operatorname{span} \{ i \sigma_1, i \sigma_3\}.

We put

\; \mathfrak{k} = \operatorname{span} \{i \sigma_3\},

and

\; \mathfrak{p} = \operatorname{span} \{ i \sigma_1, i \sigma_2\}.

Using the algebraic identities listed in the previous section, it can be verified that \mathfrak{k} and \mathfrak{p} form a Cartan pair of the Lie algebra SU(2). Furthermore,

\; \mathfrak{a} = \operatorname{span} \{ i \sigma_2\}

is a maximal abelian subalgebra of \mathfrak{p}. Now, a version of Cartan decomposition states that any element U in the Lie group SU(2) can be expressed in the form

U = e^{k_1} e^a e^{k_2}\,\! where k_1, k_2 \in \mathfrak{k} and a \in \mathfrak{a}.

In other words, any unitary U of determinant 1 is of the form

U = e^{i \gamma \sigma_3} e^{i \beta \sigma_2} e^{i \alpha \sigma_3}\,\!

for some real numbers α, β, and γ. Physically, this corresponds to the important z-y-z decomposition of a general 3D rotation.

Extending to unitary matrices gives that any unitary 2 × 2 U is of the form

U = e^{i \delta} e^{i \gamma \sigma_3} e^{i \beta \sigma_2} e^{i \alpha \sigma_3}\,\!

where the additional parameter δ is also real (also compare with Leonhardt 2010, eq 5.22, pg. 99)

SO(3)

The Lie algebra su(2) is isomorphic to the Lie algebra so(3), which corresponds to the Lie group SO(3), the group of rotations in three-dimensional space. In other words, one can say that i \sigma_j's are a realization (and, in fact, the lowest-dimensional realization) of infinitesimal rotations in three-dimensional space. However, even though su(2) and so(3) are isomorphic as Lie algebras, SU(2) and SO(3) are not isomorphic as Lie groups. SU(2) is actually a double cover of SO(3), meaning that there is a two-to-one homomorphism from SU(2) to SO(3).

Quaternions

The real linear span of \{I, i\sigma_1, i\sigma_2, i\sigma_3\}\, is isomorphic to the real algebra of quaternions H. The isomorphism from H to this set is given by the following map (notice the reversed signs for the Pauli matrices):


1 \mapsto I, \quad
i \mapsto - i \sigma_1, \quad
j \mapsto - i \sigma_2, \quad
k \mapsto - i \sigma_3.

Alternatively, the isomorphism can be achieved by a map using the Pauli matrices in reversed order,[2]


1 \mapsto I, \quad
i \mapsto i \sigma_3, \quad
j \mapsto i \sigma_2, \quad
k \mapsto i \sigma_1.

As the quaternions of unit norm is group-isomorphic to SU(2), this gives yet another way of describing SU(2) via the Pauli matrices. The two-to-one homomorphism from SU(2) to SO(3) can also be explicitly given in terms of the Pauli matrices in this formulation.

Quaternions form a division algebra—every non-zero element has an inverse—whereas Pauli matrices do not. For a quaternionic version of the algebra generated by Pauli matrices see biquaternions, which is a venerable algebra of eight real dimensions.

Physics

Quantum mechanics

j=1:


J_x = \frac{\hbar}{\sqrt{2}}
\begin{pmatrix}
0&1&0\\
1&0&1\\
0&1&0
\end{pmatrix}

J_y = \frac{\hbar}{\sqrt{2}}
\begin{pmatrix}
0&-i&0\\
i&0&-i\\
0&i&0
\end{pmatrix}

J_z = \hbar
\begin{pmatrix}
1&0&0\\
0&0&0\\
0&0&-1
\end{pmatrix}

j=\textstyle\frac{3}{2}:


J_x = \frac\hbar2
\begin{pmatrix}
0&\sqrt{3}&0&0\\
\sqrt{3}&0&2&0\\
0&2&0&\sqrt{3}\\
0&0&\sqrt{3}&0
\end{pmatrix}

J_y = \frac\hbar2
\begin{pmatrix}
0&-i\sqrt{3}&0&0\\
i\sqrt{3}&0&-2i&0\\
0&2i&0&-i\sqrt{3}\\
0&0&i\sqrt{3}&0
\end{pmatrix}

J_z = \frac\hbar2
\begin{pmatrix}
3&0&0&0\\
0&1&0&0\\
0&0&-1&0\\
0&0&0&-3
\end{pmatrix}.

Quantum information

See also

Notes

  1. ^ http://planetmath.org/encyclopedia/PauliMatrices.html
  2. ^ Nakahara, Mikio (2003), Geometry, topology, and physics (2nd ed.), CRC Press, ISBN 9780750306065 , pp. xxii.

References