Goddard–Thorn theorem

Formalism

Suppose that V is a vector space with a nondegenerate bilinear form <·,·>.

Further suppose that V is acted on by the Virasoro algebra in such a way that the adjoint of the operator L_i is L_−i, that the central element of the Virasoro algebra acts as multiplication by 24, that any vector of V is the sum of eigenvectors of L₀ with non-negative integral eigenvalues, and that all eigenspaces of L₀ are finite-dimensional.

Let Vⁱ be the subspace of V on which L₀ has eigenvalue i. Assume that V is acted on by a group G which preserves all of its structure.

Now let V I I 1 , 1 be the vertex algebra of the double cover I ^ I 1 , 1 of the two-dimensional even unimodular Lorentzian lattice I I 1 , 1 (so that V I I 1 , 1 is I I 1 , 1 -graded, has a bilinear form (·,·) and is acted on by the Virasoro algebra).

Furthermore, let P¹ be the subspace of the vertex algebra V ⊗ V I I 1 , 1 of vectors v with L₀(v) = v, L_i(v) = 0 for i > 0, and let P r 1 be the subspace of P¹ of degree r ∈ I I 1 , 1 . (All these spaces inherit an action of G from the action of G on V and the trivial action of G on V I I 1 , 1 and R²).

Then, the quotient of P r 1 by the nullspace of its bilinear form is naturally isomorphic (as a G-module with an invariant bilinear form) to V 1 − ( r , r ) / 2 if r ≠ 0, and to V 1 ⊕ R 2 if r = 0.

Applications

The theorem can be used to construct some generalized Kac–Moody algebras, in particular the monster Lie algebra.