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Next: Representations of Weyl algebras Up: Uncertainty principle Previous: Eigen vectors

Representations

In abstract algebra, we may find another way of describing the uncertainty principle. We first define the algebra generated by the operators appeared in the preceding subsection.

$\displaystyle A_n(k)=k\langle x_1,x_2,\dots,x_n,\partial_1,\partial_2,\dots,\partial_n
\rangle
$

We call it the Weyl algebra over $ k$ . Here, $ k$ is the field $ \mathbb{C}$ of complex numbers in the physics context, but may well be a domain of characteristic 0 .

In general, including the case where the characteristic of the ground field $ k$ is non zero (or even the case where $ k$ is an arbitrary ring), we define as follows.

DEFINITION 6.1   Let $ n$ be a positive integer. A Weyl algebra $ A_n(k)$ over a commutative ring $ k$ is an algebra over $ k$ generated by $ 2 n$ elements $ \{\gamma_1,\gamma_2,\dots,\gamma_{2 n}\}$ with the ``canonical commutation relations'' (CCR)

$\displaystyle [\gamma_i \gamma_j]=h_{i j} \qquad (1\leq i,j \leq 2 n).
$

Where $ h$ is a non-degenerate anti-Hermitian $ 2 n \times 2 n$ matrix of the following form.

$\displaystyle (h)=
\begin{pmatrix}
0 & -1_n \\
1_n & 0
\end{pmatrix}.
$

In what follows, $ h$ will always mean the matrix above. we denote by $ \bar{h}$ the inverse matrix of $ h$ .

LEMMA 6.2   Any element $ a$ of $ A_n(k)$ is written uniquely as

$\displaystyle \sum_{i_1,i_2,i_3,\dots,i_{2n}} a_{i_1,i_2,i_3,\dots, i_{2n}}
\gamma_1^{i_1}
\gamma_2^{i_2}
\gamma_3^{i_3}
\dots
\gamma_{2 n}^{i_n}
$

Then the fact is:

LEMMA 6.3   Assume $ k$ is a field of characteristic zero. Then the Weyl algebra $ A_n(k)$ is simple (that means, has no proper two-sided ideals). There exists no finite dimensional representation of $ A_n(k)$

PROOF.. Let $ \mathfrak{a}$ be a non trivial two-sided ideal of $ A_n(k)$ . We take a non zero element $ x \in \mathfrak{a}$ with the lowest degree when expressed as a polynomial of $ \gamma$ .

$\displaystyle x=\sum_{I} x_I\gamma^I
$

Then it is easy to see that the commutator $ [\gamma_i,x]$ has the degree lower than $ x$ , and that one of the commutators is non zero unless $ x$ is a constant.

From the manner we choose the element $ x$ , we deduce that $ x$ should be a non zero constant in $ \mathfrak{a}$ . That means,

$\displaystyle \mathfrak{a}=A_n(k).
$

This is contrary to the assumption that $ \mathfrak{a}$ is non trivial.

$ \qedsymbol$

When the characteristic of the base field $ k$ is not zero, things are different. We shall see this in the next section.

Before that, we make an easy explanation for the latter part of the Lemma above. Let

$\displaystyle \alpha: A_n(k)\to M_d(k)
$

be a finite dimensional representation. Then taking a trace of the CCR relations we obtain

$\displaystyle 0=
\operatorname{tr}{[\alpha(\gamma_{n+i}) \alpha( \gamma_i)]}
=
...
...ratorname{tr}{\alpha([\gamma_{n+i} \gamma_i])}
=\operatorname{tr}(\alpha(1))=d
$

which is absurd.
next up previous
Next: Representations of Weyl algebras Up: Uncertainty principle Previous: Eigen vectors
2007-04-20