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Categories: Lie groups | Quantum field theory | Conformal field theory

Wess-Zumino-Witten model

In theoretical physics and mathematics, the Wess-Zumino-Witten (WZW) model, also called the Wess-Zumino-Novikov-Witten model, is a simple model of conformal field theory whose solutions are realized by affine Kac-Moody algebras. It is named after Julius Wess , Bruno Zumino , Sergei P. Novikov and Edward Witten.

Contents

1 Action

1.1 Pullback
1.2 Topological obstructions
1.3 Generalizations

2 Current algebra

Action

Let G denote a compact simply-connected Lie group and g its simple Lie algebra. Suppose that γ is a G-valued field on the complex plane. More precisely, we want γ to be defined on the Riemann sphere $S 2$ , which is the complex plane compactified by adding a point at infinity.

The WZW model is then a nonlinear sigma model defined by γ with the action given by

$S_k(\gamma)= - \, \frac {k}{8\pi} \int_{S^2} d^2x\, \mathcal{K} (\gamma^{-1} \partial^\mu \gamma \, , \, \gamma^{-1} \partial_\mu \gamma) + 2\pi k\, S^{\mathrm WZ}(\gamma)$ .

Here, $\partial_\mu = \partial / \partial x^\mu$ is the partial derivative and the usual summation convention over indices is used, with a Euclidean metric. Here, $\mathcal{K}$ is the Killing form on g, and thus the first term is the standard kinetic term of quantum field theory.

The term S^WZ is called the Wess-Zumino term and can be written as

$S^{\mathrm WZ}(\gamma) = - \, \frac{1}{48\pi^2} \int_{B^3} d^3y\, \epsilon^{ijk} \mathcal{K} \left( \gamma^{-1} \, \frac {\partial \gamma} {\partial y^i} \, , \, \left[ \gamma^{-1} \, \frac {\partial \gamma} {\partial y^j} \, , \, \gamma^{-1} \, \frac {\partial \gamma} {\partial y^k} \right] \right)$

where [,] is the commutator, $ε i j k$ is the completely anti-symmetric tensor, and the integration coordinates $y i$ for i=1,2,3 range over the unit ball $B 3$ . In this integral, the field γ has been extended so that it is defined on the interior of the unit ball. This extension can always be done because the homotopy group $π 2 (G)$ always vanishes for any compact, simply-connected Lie group, and we originally defined γ on the 2-sphere $S^2=\partial B^3$ .

Pullback

Note that if $e a$ are the basis vectors for the Lie algebra, then $\mathcal{K} (e_a, [e_b, e_c])$ are the structure constants of the Lie algebra. Note also that the structure constants are completely anti-symmetric, and thus they define a 3-form on the group manifold of G. Thus, the integrand above is just the pullback of the harmonic 3-form to the ball $B 3$ . Denoting the harmonic 3-form by c and the pullback by $γ *$ , one then has

$S^{\mathrm WZ}(\gamma) = \int_{B^3} \gamma^{*} c$

This form leads directly to a topological analysis of the WZ term.

Topological obstructions

The extension of the field to the interior of the ball is not unique; the need to have the physics be independent of the extension imposes a quanitization condition on the coupling constant k. Consider two different extensions of γ to the interior of the ball. They are maps from flat 3-space into the Lie group G. Consider now glueing these two balls together at their boundary $S 2$ . The result of the glueing is a topological 3-sphere; each ball $B 3$ is a hemisphere of $S 3$ . The two different extensions of γ on each ball now becomes a map $S^3\rightarrow G$ . However, the homotopy group $\pi_3(G)=\mathbb{Z}$ for any compact, connected simple Lie group G. Thus we have

S W Z (γ) = S W Z (γ') + n

where γ and γ' denote the two different extensions onto the ball, and n, an integer, is the winding number of the glued-together map. The physics that this model leads to will stay the same if

$\exp \left(i2\pi k S^{\mathrm WZ}(\gamma) \right)= \exp \left( i2\pi k S^{\mathrm WZ}(\gamma')\right)$

Thus, topological considerations leads one to conclude that that coupling constant k must be an integer.

Generalizations

Although in the above, the WZW model is defined on the Riemann sphere, it can be generalized so that the field γ lives on a compact Riemann surface.

Current algebra

The current algebra of the WZW model is a Virasoro algebra.

Categories: Lie groups | Quantum field theory | Conformal field theory

Last updated: 06-06-2005 03:57:26

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10-26-2009 08:16:03
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